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 GYPSUM IN 
 CALIFORNIA 
 
 BULLETIN 163 
 1952 
 
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 DIVl^ON OF MNES 
 
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THE LIBRARY 
 
 OF 
 
 THE UNIVERSITY 
 
 OF CALIFORNIA 
 
 DAVIS 
 
STATE OF CALIFORNIA 
 EARL WARREN, Governor 
 
 DEPARTMENT OF NATURAL RESOURCES 
 
 WARREN T. HANNUM, Director 
 
 DIVISION OF MINES 
 
 FERRY BUILDING, SAN FRANCISCO 11 
 OLAF P. JENKINS, Chief 
 
 San Francisco 
 
 BULLETIN 163 
 
 September 1952 
 
 GYPSUM 
 
 IN 
 
 CALIFORNIA 
 
 By WILLIAM E. VER PLANCK 
 
 LIBRARY 
 
 UNTXERollY OF CAUFC^NIA 
 DAVIS 
 
LETTER OF TRANSMITTAL 
 
 To IIlS EXCELLKNCY, TlIK IIONORAHLE EauL AVaRREN 
 
 Governor of the State of California 
 
 Dear Sir: I have the lionor to transmit herewitli liuUetiii 163, Gyj)- 
 sinn in California, prepared under tlie direetion of Ohif P. Jenkins, Chief 
 of the Division of ]\Iines. Gypsum represents one of the important non- 
 metallic mineral commodities of California. It serves particularly two 
 of California's most important industries, aprieulture and construction. 
 
 In Bulletin 163 the author, W. p]. Xev Phinek, a member of the staff 
 of the Division of Mines, has prepared a comprehensive treatise cover- 
 ing all phases of the subject : history of the industry, geologic occurrence 
 and origin of tlie minoi-al, mining, i)rocessing and marketing of the com- 
 modity. Specific g3'psum i)roperties Avere examined and mapped. The 
 report is profusely illustrated by maps, charts and photographs. In the 
 preparation of the report it was necessary for the author to make field 
 investigations, laboratory and library studies, and to determine how the 
 mineral is used in industry as Avell as how it occurs in nature and how 
 it is mined. 
 
 This bulletin represents one of the results of the program of mineral 
 commodity studies in which the Division of Mines is engaged. 
 
 Respectfully submitted, 
 
 Warren T. IIannum, Director 
 Department of Natural Resources 
 June 20, VXrl 
 
 (3) 
 
CONTENTS 
 
 Page 
 
 ABSTRACT 7 
 
 INTRODUCTION 7 
 
 The gypsum industry 8 
 
 Ccologic occurrence 9 
 
 PART 1, GEOLOGY OF CALIFORNIA GYPSUM DEPOSITS 11 
 
 Pro-Tertiary deposits 13 
 
 Little Maria Mountains deiwsits, Riverside County 13 
 
 Palen Mountains deiwsits, Riverside County 21 
 
 Riverside Mountains deposits 24 
 
 Clark Mountain deposits, San Bernardino County 24 
 
 Tertiary deposits 27 
 
 Fish Creek Mountains deposit, Imperial and San Diego Counties 29 
 
 Quatal Canyon deposit, Ventura County 35 
 
 Death Valley region 38 
 
 C uddv Can yon deposit, Kern County 39 
 
 iMint Canyon deposit, Los Angeles County 40 
 
 Mule Shoe Ranch deiwsit, San Benito County 40 
 
 Cuyania Valley deposits, Santa Barbara and Ventura Counties 41 
 
 Avawatz Mountains deposits, San Bernardino County 43 
 
 Quaternary lake (playa) dei^osits 47 
 
 Bristol Lake, San Bernardino County 47 
 
 Danby Lake 48 
 
 Recent deposits (Recent) 48 
 
 Fresno County deposits 49 
 
 Kern CoaatjL-4leposits 51 
 
 Kings County deposits 56 
 
 Los Angeles County deposits 57 
 
 Merced County deposits 57 
 
 Riverside County deposits 57 
 
 San Luis Obispo County deposits 58 
 
 Ventura County deposits 59 
 
 Origin of gypsum 59 
 
 Gypsum-anhydrite problem 61 
 
 PART 2, MINING, PROCESSING AND MARKETING OF GYPSUM 65 
 
 Mining 67 
 
 History 67 
 
 Mining methods 72 
 
 Bcneficiation 74 
 
 Processing 76 
 
 Agricultural gypsum 76 
 
 Portland cement retarder 84 
 
 Calcination of gypsum 8r» 
 
 Marketing 90 
 
 Gypsum products 90 
 
 Gypsum markets 98 
 
 Gypsum plants in California 101 
 
 APPENDIX 111 
 
 Bibliography 113 
 
 Gypsum production in California 68 
 
 Gypsum production by counties 09 
 
 Tabulated list of California gypsum deposits 120 
 
 Tabulated list of producers and owners 131 
 
 ILLUSTRATIONS 
 
 Figure 1. Index map of gypsum mines in Little Maria Mountains 14 
 
 2. Geologic map of Utah Construction Company quarry 19 
 
 3. Section through Riverside Mountains deposit 24 
 
 4. Index map showing location of Shire deposits 25 
 
 5. Geologic sections through Shire gypsum deposit 26 
 
 6. Index map showing location of Fish Creek Mountains deposit^- 28 
 
 7. Structure section through Quatal Canyon gypsum deposit 36 
 
 8. Map of Cuyama Valley gypsum deposits and structure sections 
 
 through Wagon Road Canyon deposit 42 
 
 9. Sketch map showing location of gypsite workings in Telephone 
 
 Hills 54 
 
 10. Chart showing production and average price of gypsum in Cali- 
 
 fornia 99 
 
 11. Flow sheet of gypsum grinding plant at Inca Siding 107 
 
 (B) 
 
ILLUSTRATIONS— Continued 
 
 Page 
 Plate 1. Oiitliue geologic mai* of California showing location of gypsum de- 
 posits In ixjcket 
 
 2. Geologic map of part of Little Maria Mountains In pocket 
 
 .3. Structure sections through Jattle Maria Mountains gypsum de- 
 
 ix>sit In pocket 
 
 4. IMioto of western part of gypsum belt, Little Maria Mountains 1&-17 
 
 5. Photo of north side of gypsum belt, Little Maria Mountains 16-17 
 
 6. Photo from north side of gypsum belt. Little Maria Mountains 10-17 
 
 7. A. Photo of siliceous limestone, Little Maria Mountains, B. Photo 
 
 of crumpled gypsiferous schist, Little Maria Mountains 16—17 
 
 8. Photomicrograph of tremolitic limestone 16-17 
 
 9. Photomicrograph of gypsiferous schist, plain light 16-17 
 
 10. Photomicrograph of gypsiferous schist, crossed nicols 16-17 
 
 11. Photomicrograph of non-gypsiferous green schistose rock 16-17 
 
 12. Photo of gyps.um zone bordering wash. Little Maria Mountains 24-25 
 
 13. Photo of specimen from south granitic body, Little Maria Moun- 
 
 tains 24-25 
 
 14. Photo of specimen of foliated gypsum and schist 24-25 
 
 15. Photo of Gypsum Hills, Little Maria Mountains 24-25 
 
 16. Photo of Utah Construction Company quarry 24-25 
 
 17. Photomicrograph of impure gypsum 24-25 
 
 18. Photo of detail of schist and gypsum 24-25 
 
 19. Photo of detail of schist and gypsum 24—25 
 
 20. Geologic map and sections. Fish Creek Mountains deposit In pocket 
 
 21. Photo of Fish Creek Mountains gypsum deposit 40-41 
 
 22. Photo of gypsum on west side of wash, Fish Creek Mountains 40—41 
 
 23. Photo of base of gypsum. Fish Creek Mountains 40—41 
 
 24. Photo of gray conglomerate, Fish Creek Mountains 40-41 
 
 25. Photo of sandstone-granite contact. Fish Creek Mountains 40-41 
 
 26. Photo of Gypsum Hills, Fish Creek Mountains 40-41 
 
 27. Photo of United States Gypsum Company quarry 40-41 
 
 28. Photo of base of gypsum. Fish Creek Mountains 40-41 
 
 29. Photo of gypsum and anhydrite 40-41 
 
 30. Photo of specimen of mottled gypsum 40—41 
 
 31. Photo of specimen of anhydrite 40-41 
 
 32. Photomicrograph of fibrous anhydrite 40-41 
 
 33. Geologic map of Quatal Canyon gypsum deposit In pocket 
 
 34. Geologic sections across three gypsum deposits In pocket 
 
 35. Geologic map showing gypsum- and salt-bearing rocks in Ava- 
 
 watz Mountains In pocket 
 
 36. Structure sections through Avawatz Mountains deposit In pocket 
 
 37. Photo of gypsum quarry, Monolith Portland Cement Company 56-57 
 
 38. Photo of gypsum quarry, Monolith Portland Cement Company 56-57 
 
 39. Photo of chert nodule in gypsum 5&-57 
 
 40. Photo of Monolith Portland Cement Company crushing plant 56-57 
 
 41. Photo of Cuddy Canyon gypsum deposit 56-57 
 
 42. Photo of GrifBn gypsite deposit 56-57 
 
 43. Photo of solution of cavity in gypsite 56-57 
 
 44. Photo of selenite crystals from Danby Lake 56-57 
 
 45. Photo of Lost Hills gypsite mine 60-61 
 
 46. A. Photo of Avenal Gap gypsite mine, B. Photo of Garissa gypsite 
 
 mine 60-61 
 
 47. Photomicrograph of alabaster 60-61 
 
 48. Photomicrograph of gyp.sum 60-61 
 
 49. Photomicrograph of iwriihyritic gypsum 60-61 
 
 50. Photomicrograph of gypsum and anhydrite 60-61 
 
 51. Photomicrograph of fibrous gypsum 60-61 
 
 52. Photo of Monolith workings.^ 60-61 
 
 (6) 
 
GYPSUM IN CALIFORNIA 
 By William E. Ver Planck • 
 
 ABSTRACT 
 
 The know II >;ypsum rosourcps of California aro restricted to the southern and south- 
 enstern parts of the state. Gypsum (CaS0<-2II-0) most commonly occurs as rock 
 pyi)sum of liiuli purity interhfddcd with saline deposits or clastic sediments or as the 
 efilorescent, earthy variety fcypsite with a jjypsum content ranginK up to 80 per cent. 
 Gypsum of prc-Tertiary, possibly Paleoz<dc, age is represented by deposits near Mid- 
 land, Riverside County, where steeidy dipping lenses and beds of coarsely crystalline 
 rock )ryps""i are associated with mildly metamorphosed marble and clastic sediments. 
 Tertiary gyiisum deposits in California, associated with late Miocene or early IMioccne 
 non-marine sediments, are represented bj' the Fish Creek Mountains deposit, Imi)erial 
 and San Diego Counties, the Quatal Canyon deposit, Ventura County, and by a number 
 of small deposits in the Death Valley area and other parts of the state. Certain playas 
 contain abundant coarse selenite crystals that have been mined. Gypsite deposits, 
 formed by the evapi>ration tif frypsuni-ix'ariiii; ground water, occur in refrifms of little 
 rain and hi^'h evaporation. Gj'psite is niined in the southwestern part of the San Joatiuin 
 Valley, at Koehn Lake, Kern County, Carrizo Plain, San Luis Obispo County, and 
 has been mined el.sewhere in the past. Rock pypsum is quarried by methods and equip- 
 ment commonly used for obtainiiiK liroken stone. Underground mining has been prac- 
 ticed. Gypsite is mined with carryall scrajters and other earth-moving equipment. Agri- 
 cultural uses account for about half of the gypsum used in California, most of which 
 is used in the San Joaquin Valley. An estimated 90 per cent of the agricultural gyjisum 
 is gypsite mined within 200 miles of the farms, and the remainder is ground rock 
 gypsum. The portland cement industry uses uncalcined rock gypsum as a retarder. Most 
 of the rock gypsum produced in California, supplemented by gypsum brought from 
 Gerlach and Las Vegas, Nevada and from San Marcos Island in the Gulf of California, 
 is calcined by the plaster industry and made into plasters, wallboard, and lath. The 
 plaster industry is characterized by large integrated companies that own their own 
 gypsum deposits. California has five calcining plants, one in the San Francisco Bay 
 area, two near Los Angeles, and two in the southeastern desert close to gypsum deposits. 
 The metropolitan plants obtain gypsum from out-of-state sources. 
 
 INTRODUCTION 
 
 No complete study of the p:ypsum resources of California has previously 
 been published. There are, however, two geologic studies; both were made 
 when the California gypsum industry was in its infancy. The work of 
 Fairbanks ^ comprises a few remarks about the location and general char- 
 acter of the California deposits and brief descrii)tions of 15 localities. In 
 the winter of 1906 and 1907. F. L. ITess studied most of the then important 
 deposits and prepared the most complete published description.^ Hess was 
 among the first to realize the superficial character of the gypsite deposits. 
 In 1920 Iless' work was republished substantially in its original form, 
 together with some additional data contributed by other authors.^ 
 
 The mining and processing of gypsum in California has not been sum- 
 marized although individual operations have been described in reports 
 of the California Division of Mines. 
 
 In the present report, the geologic occurrence, mining, preparation, 
 and utilization of gypsum are described. Except where noted, only those 
 deposits and operations actually visited are described in the text ; they, 
 
 • Assistant Mining Geologist, California Division of Mines. Manuscript submitted for 
 publication February, 1952. . . .^ ^ , ^ ti. /-. 
 
 1 Fairbanks, H. W., Gvpsum deposits in California, m Adams, G. I and others. Gypsum 
 deposits in the United States : U. S. Geol. Survey Bull. 223, pp. 119-123 1904 
 
 ' Hess, F. L., A reconnaissance of the gypsum deposits of California: U. S. Geol. Survey 
 
 8 Hess F L, California, in Stone, R. W., and others, Gypsum deposits of the United 
 States : U. S. Geol. Survey Bull. 697, pp. 58-86, 1920. 
 
 ( 7 ) 
 
8 GYPSUM IN CALIFORNIA [Bull. 163 
 
 together with all others mentioned in the literature, are included in the 
 tabulated lists. The numbers following deposit, mine, or plant names refer 
 to the numbered localities on the index map (plate 1). 
 
 Time permitted the detailed geologic study of only three gypsum de- 
 posits, which are representative of the types found in California. They 
 are the Little Maria Mountains deposit, studied in February and March 
 1949, the Fish Creek Mountains deposit, studied in March and April 1950, 
 and the Quatal Canyon deposit, studied in May 1950. The Little ]\Iaria 
 Mountains study was undertaken as a thesis submitted to the School of 
 Mineral Science and the Committee on Graduate Study of Stanford Uni- 
 versity in partial fulfillment for the degree of Master of Science. This 
 material has been modified for inclusion here. Thirty-seven other deposits 
 were visited and are described briefly, some with the aid of large-scale 
 geologic cross sections. The location and accessibility of the deposits was 
 emphasized. 
 
 The descriptions of the processing plants are based on plant visits, sup- 
 plemented by recently published descriptions. Unfortunately, it was not 
 possible to visit plants of the United States Gypsum Company. 
 
 The Gypsum Industry 
 
 During 1949 the gypsum industry of the United States produced gyp- 
 .sum and gypsum products valued at $158,746,367. California was ex- 
 ceeded only by Michigan and New York in the tonnage of gypsum mined 
 in 1948 but slipped into fourth place in 1949. 
 
 The uses of gypsum are many. It is used uncalcined as an agricultural 
 mineral. In California as much as half the total production has been used 
 for agricultural purposes, although for the United States as a whole 
 gypsum plaj's a minor role in agriculture. In 1949 nearly 80 percent of 
 the agricultural gypsum consumed in the United States was sold in Cali- 
 fornia. The Portland cement industry is another large consumer of un- 
 calcined gypsum. Added in the amount of 2 to 3 percent to the clinker 
 before the final grinding, gypsum retards the setting of the cement. Other 
 minor uses for uncalcined gypsum include fillers, brewer's fixe, black- 
 board chalk, and many others. Alabaster of good color and high quality 
 is suitable for carving. 
 
 GjTpsum that has been partly dehydrated by calcining at low heat is 
 known as plaster of Paris, a material that possesses the useful property of 
 setting when mixed with water. Much of the country's output of calcined 
 gypsum is consumed by the building industry. Hardwall plaster is cal- 
 cined gj^psum to which has been added fiber and a retarder. Smaller 
 quantities of sanded plaster, gaging plaster, and many special types of 
 plaster are used in building. A large proportion of the gypsum supply is 
 made into prefabricated articles. Of very great importance is gypsum 
 wall board, lath, and sheathing board. Gypsum tiles of many sizes and 
 shapes are consumed in smaller quantities. In addition there are a great 
 many industrial processes that require special plasters of high quality. 
 There are plasters for the plate glass and terra-cotta industries, for 
 pottery, for orthopedic and dental use, for statuarj^ for industrial cast- 
 ing and molding, for polishing, and for many other purposes. 
 
 Gypsum is a low-priced commodity. The average value of crude gypsum 
 at the mine reported by United States producers in 1949 was $2.75 per 
 short ton, while the average value of gj^psum mined in California was 
 about $2.45 a ton. The price of finished products ranges from about $10 
 
INTRODUCTION 9 
 
 to ovor $70 a ton. avcra^'-inu' pcrliaps J+^lfj.OO. It is apparoit tliat llio gyp- 
 sum industry is cssfMitially a inauut'acturinir industry. 
 
 Gypsum is a broadly distributed commodity. The utilization of a 
 pypsum deposit depends usually on economic rather than technical 
 factors. Faf'tors of importance include cost of mining, cost of trans- 
 j^ortation, and the cost of manufacture which in turn is iiifluenced by 
 the si/.e of the mai'ket available to the plant. 
 
 Tn California frypsum deposits exist in 14 of the 58 countios. The 
 larirest reserves lie in the southeastern deserts; deposits of possible com- 
 mercial interest are not known iiorth of ]\Ierced County. Rock jrypsum 
 of 00 percent or better <iypsum content is mined in the Fish Creek IMoun- 
 tains. Imperial County; the Little Maria IMountains, Riverside County; 
 and Quatal Canyon, A'entura County. Larue but undeveloped reserves 
 are to be found in the Pah'ii IMountains and Riverside IMountains of 
 Riverside County and in the Avawatz IMountains of San Bernardino 
 County. IMuch of the prypsura used for ap:ricultural purposes is prypsite 
 that contains from 70 percent to less than 50 percent jrypsum. Gypsite 
 mininir is centered in the west side of the San Joaquin Valley from 
 I\rclvittrick in Kern County to Ortigalita Creek in IMcrced County. 
 
 California is supplied Avith crude gypsum from two other sources. 
 Synthetic jrypsum is a byproduct of several chemical processes. At pres- 
 ent it is produced by tlie Westvaco Chemical Division, Food Machinery 
 and Chemical Corporation at Newark, Alameda County, in connection 
 with the manufacture of sea water magnesia. Much gypsum comes from 
 out-of-state sources. Since the earliest days of the California gypsum 
 industry, gypsum has been shipped from San Marcos Island near Santa 
 Rosalia in the Gulf of California. The amount of gypsum imported from 
 San IMarcos Island in 1049 amounted to a fifth of that produced by Cali- 
 fornia mines. In addition both crude gypsum and g3^psum products come 
 from Gerlach aiul Arden, Nevada. 
 
 The California gypsum industry is centered in southern California, 
 and four of the five calcining plants are located there. These plants con- 
 sume gypsum mined in California supplemented by supplies from out- 
 of-state sources. Northern California is largely dependent on out-of-state 
 sources for both crude gypsum and manufactured gypsum products. 
 
 Geologic Occurrence 
 
 Gypsum (CaSOi -211-0) and anhydrite (CaS04) are the two naturally 
 occurring solid phases of the system CaS04 — H2O. Several additional 
 members can be prepared in the laboratory under controlled conditions. 
 These include tAvo forms of the hemihydrate (CaS04-^n20) and two 
 forms of soluble anhydrite which may contain as much as 1 percent IIoO. 
 All four of these unstable members may form in the commercial calcining 
 kettle and are therefore of more than theoretical interest. 
 
 Pure gypsum is composed of 32.5 percent CaO, 46.6 percent SO3, and 
 20.0 percent ILO. It crystallizes in the monoclinic system. Perfect cleav- 
 age in one direction and hardness of 2 are diagnostic properties. Gypsum 
 may be transparent to opaque, and white, gray, yellowish, or browni.sh 
 in color. It is slightly soluble in water but dissolves readily in hot hydro- 
 chloric acid without effervescence. 
 
 Most commercial gypsum is a massive fine- to medium-grained material 
 known as rock g}-psum. Often it contains as much as 10 percent of silica 
 
10 GYPSUM IN CALIFORNIA [Bull. 163 
 
 and calcium carbonate, and it may be dark-colored. Some finc-p:rained 
 impure gypsum cannot be readily scratched M'ith the fingernail. Gypsite, 
 an earthy mixture of very small gypsum crystals and clay or sand, is 
 also important commercially. Alabaster is fine-grained, white, often trans- 
 lucent, rock gypsum suitable for carving. Crystalline gypsum, known 
 as selenite, occurs in transparent, cleavable masses or crystals. Satin spar 
 is fine, fibrous, silky lustered gypsum that is found in veins of ground 
 water origin. Ordinarily selenite and satin spar arc not commercial 
 sources of gypsum. 
 
 Anhydrite is composed of 41.2 percent CaO and 58.8 percent SO3. It 
 occurs in crystalline masses, usually granular but sometimes fibrous, that 
 are white to pale shades of gray, blue, or red. Having a hardness of 3 to 
 3.5 and specific gravity of 2.89 to 2.98 it may be confused with limestone 
 or dolomite in the field. Under the petrographic microscope anhydrite 
 may be distinguished from both calcite and gypsum by its rectangular 
 cleavage, moderate relief, and second to third order birefringence. 
 
 Gypsum is nearly always associated with anhydrite. Much evidence 
 indicates that gypsum is the stable phase of calcium sulfate at the sur- 
 face and that at depths of two to three hundred feet calcium sulfate is 
 likely to occur as anhydrite. 
 
 The largest and commercially most important deposits are rock gypsum 
 interbedded with sedimentary rocks. In California rock gypsum occurs 
 in Tertiary non-marine clay and arkosic sand and in pre-Tertiary lime- 
 stone that has been subjected to mild regional metamorphism. The earthy 
 variety gypsite that forms on the outcrops of gypsiferous formations in 
 arid regions contributes a substantial proportion of the California pro- 
 duction. The crystal bodies of certain playa lakes are rich enough in 
 gypsum to be possible commercial sources. Gypsum and anhydrite are 
 also known to occur as part of the gangue in hydrothermal veins and as 
 replacements of limestone. Near-surface veins formed by deposition from 
 ground water are frequently found but are rarely a commercial source 
 of gypsum. 
 
PART 1 
 
 GEOLOGY OF CALIFORNIA 
 GYPSUM DEPOSITS 
 
PART 1 
 
 CONTENTS 
 
 Page 
 
 Pre-Tertiary deposits 13 
 
 Little Maria Mountains deposits, Riverside County 13 
 
 Stratigraphy 14 
 
 Structure 18 
 
 The Utah Construction Compauy quarry 18 
 
 Palen Mountains deposits, Riverside County 21 
 
 Riverside Mountains deposits 24 
 
 Clarli Mountaiu deposits, San Bernardino County 24 
 
 Tertiary deposits 27 
 
 Fish Creek Mountains deposit. Imperial and San Diego Counties 29 
 
 Stratigraphy 29 
 
 Structure 32 
 
 Gypsum deposits 32 
 
 Quatal Canyon deposit, Ventura County 35 
 
 Death Valley region 38 
 
 China Ranch deposit 38 
 
 Copper Canyon deposit 39 
 
 Furnace Creek deposit 39 
 
 Owl Hole Spring deposit 39 
 
 Cuddy Canyon deposit, Kern County 39 
 
 Mint Canyon deposit, Los Angeles County 40 
 
 Mule Shoe Ranch deposit, San Benito County 40 
 
 Cuyama Valley deposits, Santa Barbara and Ventura Counties 41 
 
 Avawatz Mountains deposits, San Bernardino County 43 
 
 Quaternary lake (playa) deposits 47 
 
 Bristol Lake, San Bernardino County 47 
 
 Danby Lake 48 
 
 Recent deposits (Recent) 48 
 
 Fresno County deposits 49 
 
 Little Panoche Valley deposit 49 
 
 Panoche Hills deposits 50 
 
 Tumey Gulch deposits 50 
 
 Kern County deposits 51 
 
 Kern Lake deposits 51 
 
 Koehn Lake deposits , 52 
 
 Lost Hills deposits 52 
 
 McKittrick deposits 53 
 
 Packwood Canyon deposit 56 
 
 Kings County deposits 56 
 
 Avenal Gap mine 56 
 
 Los Angeles County deposits 57 
 
 Palmdale deposits 57 
 
 Merced County deposits 57 
 
 A. D. Sousa deposit 57 
 
 Riverside County deposits 57 
 
 Corona deposits 57 
 
 San Luis Obispo County deposits 58 
 
 Carrisa mine 58 
 
 Shandon deposit 58 
 
 Ventura County deposits 59 
 
 Fillmore deposit 59 
 
 Origin of gypsum 59 
 
 Gypsum-anhydrite problem 61 
 
 (12) 
 
Parti] GEOLOGY 13 
 
 PRE-TERTIARY DEPOSITS 
 
 Gypsum deposits of pre-Tcitiai-y age oeeur in eastern Riverside 
 County and are best known in the United States Gypsum Conipau}' and 
 Garbutt and Orcutt properties in the Little ]\[aria ^lountains near ]\Iid- 
 land. The gypsum, a coarse-grained material of high purity, occurs 
 interbedded with steeply dipping limestone, quartzite, and green schis- 
 tose rocks. The Little IMaria jNIountains deposit extends eastward into 
 tlie Maria ^lountains; jMiller"* has proposed the name ]\Iaria formation 
 for the gypsum-bearing rocks. From crinoid remains found in limestone 
 a.ssoeiated with the gypsuni the age was determined to be Paleozoic, pos- 
 sibly Silurian,-'' but the Maria formation miglit be tlic metamorphosed 
 eciuilvalent of tlie gypsum-bearing Mocnkopi or Kail)ab formations of 
 Clark County, Nevada, 
 
 Deposits similar to those of the Maria and Little Maria I\Iountaius 
 oi-our in the Palon ]\Iountains and Riverside ]\Iountains, but only develop- 
 ment work lias been done. 
 
 Little Maria Mountains Deposits, Riverside County 
 
 The gypsum deposits of the Little Maria Mountains were for a 15-year 
 period prior to 1940 the largest single source of gypsum in California. 
 Since that time production has remained about the same, but as a gypsum- 
 producing district the region has been overshadowed by other areas. 
 The gypsum deposits occur in a belt of pre-Cretaceous rocks that crosses 
 the Little jMaria Range at a point about 25 miles northAvest of Blythe. 
 The same rocks extend eastward into the jMaria ISIountains where gypsum 
 deposits also exist. The town of IMidland lies on this belt in the pass 
 between the Little IMaria and Maria Mountains. The Blj'the-Rice road, 
 which pa.sses through jMidland, is paved between Blythe and Midland ; 
 and ^lidland lies on the Ripley branch of the Santa Fe railroad. 
 
 Two gypsum producers have been active in the area. First and fore- 
 most is the United States Gypsum Company, primarily a producer of 
 calcined gypsum products, whose plant is at ^Midland. Raw gypsum is 
 obtained from several mines in the eastern half of the Little Maria 
 Mountains gypsum belt (68), and the company owns gypsum deposits 
 in the JMaria ^Mountains also. The second producer, the Utah Con.struc- 
 tion Company, produced agricultural gypsum. The mine is on the west 
 side of the Little Maria jMountains ; and the grinding plant and shipping 
 point was at Inca Siding, a station 5 miles south of ^Midland. Most of the 
 description that follows is based on studies of the Garbutt and Orcutt 
 j)roperty (64), the deposit that was worked by the Utah Construction 
 Company. The area mapped (pis. 2, 3) is immediately west of the prin- 
 cipal United States Gypsum Company workings. 
 
 The American Gypsum Company leased the Garbutt and Orcutt 
 l)roperty " (64) which consists of five claims located in sees. 2, 10 and 
 11, T. 4 S., R. 20 E., SBM. These claims were patented about 1920. The 
 deposit was explored by diamond drilling in 1945, and mining began in 
 1947. The Utah Construction Company was engaged to do the work, and 
 
 * Miller, "W. J., Geology of the Palm Springs-Blythe strip, Riverside County, California : 
 
 California Div. Mines Rept. 40, p. 25, 1044. 
 5 Miller, W. J., op. cit., p. 28. 
 
 " Tucker, W. B., and SanTpson, R. J., Riverside County : California Div. Mines and 
 Mining Rept. 25, p. 510, 1929. 
 
14 
 
 GYPSUM IN CALIFORNIA 
 
 [Bull. 163 
 
 in 1948 this company acquired an interest in the property. It was closed 
 in June 1950. 
 
 Workings consist of an open pit in which disconnected benches at two 
 levels have been developed. Broken gypsum was crushed in a primary 
 jaw crusher at the quarry and trucked over an improved gravel road 7 
 miles long to the grinding plant at Inca Siding. The product was guaran- 
 teed to contain 93 percent gypsum. The operation is described in another 
 section of this study. 
 
 Figure 1. Index map showing locations of gypsum mines in the Little Maria Mountains. 
 
 Stratigraphy 
 
 No geologic description of the Little Maria Mountains is known to the 
 author, and very little has been published on the geology of the gypsum 
 deposits. Surr '^ has prepared a cross section through the central part 
 of the gypsum belt, and Miller ^ has described briefly similar gypsum 
 beds, probably an extension of the Little Maria Mountains deposit, 10 
 miles south and east of the area under consideration. Miller designated 
 these beds the Maria formation of probable Paleozoic age. 
 
 The rocks of the gyjjsum belt are crystalline limestone, quartzite, and 
 green schistose rocks, that in general strike N. 70° E. across the range 
 and occupy a low pass. The sediments are bordered on the south by 
 granite and gneiss that extend to the tip of the range ; to the north 
 granitic rocks extend for about 2 miles, and limestone lies beyond. 
 
 ■^ Surr, Gordon, Gypsum in the Maria Mountains of California: The Mining World, vol. 
 
 34, pp. 787-790, April 15, 1911. 
 8 Miller, W. J., Geology of the Palm Springs-Blythe strip : California Div. Mines Rept. 40, 
 
 pp. 25-28, 1944. 
 
Part 1] 0E0IX50Y 15 
 
 Tlie deposit has been "conimonly ••onsidered" " to bo of pre-Cambrian 
 aj?e. Miller,'" who mapped part of the Maria Mountains 10 miles to tlie 
 east, found crinoid fraj,'ments in similar roeks and states that their age 
 is post-Cambrian, perhaps Silurian. The writer found no fossils in the 
 area described nor any other indication of the age of the rocks. 
 
 Green Schistose Backs. The central part of the gypsum belt is oc- 
 cupied by green colored feldspathic (juartzite and schist. Several recog- 
 nizable types occui- in bamls several hundred feet wide that may repre- 
 sent original bedding. ]\Iost of the material is well-foliated, and the 
 foliation is parallel to the bedding of adjacent rocks. Much of the schistose 
 rock is a greenish-gray, fine- to medium-grained feldspathic quartzite 
 that Avhen weathered has a granular appearance. Quartz and albite form 
 a ground mass with xenoblastic texture in which the average grain 
 diameter is 0.02 inch. Some of the albite grains are as much as three 
 times the average size. Epidote. biotite, and tremolite are concentrated 
 in sub-parallel streaks. Epidote forms granular aggregates arranged in 
 layers parallel to (lakes of biotite. Tremolite occurs as tiny needles, both 
 in aggregates and as individuals in albite grains. 
 
 Another type of feldspathic quartzite, usually found close to gypsum, 
 is of much finer grain and breaks into sharp-edgetl, blocky fragments. 
 In thin section it resembles the granular quartzite except that the pro- 
 portion of epidote, tremolite, and biotite to quartz and albite is smaller 
 in the blocky quartzite. 
 
 A third type is a green-colored gypsiferous schist. Throughout the cen- 
 tral area of green schistose rocks are bands and patches of soft gypsiferous 
 soil, but without exception the underlying rock, wherever exposed by 
 trenching, is a thinly laminated schist with no visible gypsum. The 
 microscope reveals that the gypsiferous schist is much like the feldspathic 
 quartzites except that gypsum comprises about 15 ])erccnt of the xeno- 
 blastic ground mass. Biotite, epidote. and tremolite together comprise 
 about 30 percent of the rock. 
 
 Limestone. Flanking the central area of green schistose rocks on 
 both sides of the gypsum belt is 700 to 900 feet of limestone with intcr- 
 beddcd gypsum zones. The gypsum bodies are described below. Most of 
 the limestoiic is a tough, unfractured. fine-grained crj'staliine limestone 
 that is nearly white when fresh but buff-colored on weathered surfaces. 
 Where these beds are steeply dipping they rise in wall-like, talus-flanked 
 ridges as much as TOO feet above the general level of adjacent rocks. 
 
 The contact of the limestone with the green schistose rocks is irregular 
 in detail, and the limestone close to it contains tremolite. The tremolitic 
 limestone is of a golden brown color, and glassy tremolite prisms as 
 much as j',, inch long that are oriented in a plane parallel to the foliation 
 give the rock a micalike sparkle. There are bands of feldspathic quartzite 
 and schist on the limestone side of the contact and irregular pods of 
 tremolitic limestone within the schistose rocks. Gypsum bodies, some of 
 mineable width, occur on both sides of the contact. 
 
 In contrast with the buff limestone are beds of a dark-weathering lime- 
 stone that contain streaks and blebs of silica. Several foliation planes 
 
 » Moore, B. N., Gypsum, in Mineral resources of the region around Boulder Dam: U. S. 
 
 Geol. Survey, Bull. 871, p. 166, 1936. 
 10 Miller, W. J., op. cit., p. 28. 
 
16 GYPSUM IN CALIFORNIA [BuU, 163 
 
 give the rock a splintered appearance. This siliceous limestone may be 
 traced across the entire area mapped on the north side of the gypsum 
 belt, and is prominent on the south side also. 
 
 Quartzite. Beyond the buff limestone that contains the gypsum zones 
 the sequence of the rocks on the north side of the gypsum belt is com- 
 pletely different from that on the south side. On the north the limestone 
 is overlain by five to six hundred feet of tan-white quartzite. The quartzite 
 is faintly banded, and is so brecciated that sound pieces greater than 
 a foot in diameter are uncommon. Quartz in equidimensional interlock- 
 ing grains makes up 90 percent of the rock, while albite and sparsely 
 distributed flakes of biotite complete the mineral assembly. The quartzite 
 forms smooth talus-covered slopes, and exposures are not common. 
 
 North Limestone. The quartzite grades on the north into one to two 
 thousand feet of fine-grained crystalline limestone containing some beds 
 of quartzite as much as 50 feet thick. The limestone is tan when fresh, 
 but weathered surfaces are dark brown. This unit has been brecciated, 
 and the limestone members but not the quartzite members have been 
 recemented with calcite. Many specimens of all kinds of limestone 
 described were tested with acid, but none were dolomitic. 
 
 North Granite. The northern limit of the gypsum belt is a nearly 
 vertical fault along which the north limestone is in contact with a granitic 
 body that extends northward for at least 2 miles. Although not enough 
 specimens were examined to determine the composition of this body, one 
 specimen selected at random is quartz monzonite. Average grain size is 
 about iV inch. It is composed of quartz, 35 percent ; microcline, 25 per- 
 cent ; oligoclase, 25 percent ; and biotite, 5 percent. Biotite is in the form 
 of clusters of small crystals. Many of the feldspar grains, especially 
 oligoclase, have been replaced by sericite and by epidote. 
 
 South Granite. The ridge south of the gypsum belt is composed of 
 coarse-grained gneissic granite that is quite different from the granite 
 to the north. Foliation is pronounced on weathered surfaces but not 
 evident in the fresh rock. The rock is characterized by lavender-colored 
 phenocrysts of microcline and albite feldspar up to \ inch long. There 
 are quartz grains almost as large as the feldspars, some biotite, and a 
 minor proportion of sphene and magnetite. The albite crystals have been 
 largely replaced with sericite, epidote, and calcite. 
 
 Undifferentiated Metamorphic Focls. The relations between the 
 south granite and the gypsum belt are not clear. Between the granite and 
 the buff limestone containing the gypsum zones are feldspathic quarzites 
 and gneisses that have not been ditferentiated in mapping. The foliation 
 of the metamorphic rocks seems to conform with both the foliation of 
 the south granite and the bedding of the limestone. Light-colored 
 quartzite close to the limestone contains porphyroclasts of quartz and 
 microcline 0.1 inch in size. Toward the granite the quartzite becomes 
 darker, contains more biotite, and grades into gneiss with abundant 
 large porphyroclasts that have been elongated and crushed. 
 
 Possible Dikes. The only igneous rock found besides the granites was 
 a thin body of altered andesite that occurs in tremolitic limestone between 
 

 
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DIVISION OF MINKS 
 
 BUI^LETIN 163, PLATE 7 
 
 -»«>. 
 
 :f 
 
 A. Sll.U'KUl'S LIMESTONE 
 
 Little Maria Mountains. View along strike from the wash 
 that flows west of the I'tah Construction Company quarry. 
 
 <^ 
 
 .V 
 
 ^_. 
 
 f-*MH. . jftjjj^: 
 
 ■4WfV" « ' 
 
 ^: 'iL-d&t& 
 
 H. CKl'.MPLKl) C.VPSIFEIUHS SCHIST 
 
 Little Maria Mountains. Crumpled gypsiferous schist, Little Maria 
 Mountains. Cypsum soil that covers the schist appears at the top of 
 
 the photograph. 
 
i)i\'isn i\ I ii'' M I .\i:s 
 
 i;II.i.i;tix If.::, I'l.ATK s 
 
 
 
 ,»► 
 
 4' ''>v •-'*^- > / 
 
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 I 
 
 IMK iToMlCltoCKAril OF TKi:.\U)l.ITU" hi M lOSToX K 
 
 I.itU.- Maria Mmintains. I-'ield consists of gray calcite and wliite tremolito. 
 
 riain lipht. 
 
DIVISIOX OF MINES 
 
 BIILT.KTIN lf,:i, I'l.ATR Jt 
 
 
 
 
 
 L. 
 
 005 in. 
 
 PHOTOMICROGRAPH OF GYPSIFEROUS SCHIST, PLAIN LIGHT 
 Little Maria Mountains. Fibrous gypsum, iiuartz, and albite form a groundmass in wliich 
 clusters of epidote crystals and rougiily oriented flakes of liiotite are imperfectly segre- 
 gated into bands. 
 
DIVISION OF MINKS 
 
 jMM.ioTiN n;:!, im.atI': lo 
 
 
 
 L. 
 
 005 in. 
 
 1 
 
 I'HC^To.MICItoCKAr'}^ OF (ni'Sl FIOROFS SCHIST, CUOSSED NICOLS 
 
DIVISION OF MINES 
 
 BUI^LETIN ICn, PLATE 11 
 
 ^i -.. 
 
 
 ^■^^-1^^^ 
 
 
 
 
 
 -K *, ^ *• 
 
 
 
 i— 
 
 005 in. 
 
 — I 
 
 PHOTOMICROGRAPH OF NON-OYPSIFEROHS GREEN SCHISTOSE ROCK 
 
 liittle Maria Mountains. Biotite, fi)idiite, and iremolite (needles) in a Rranoljlastii; 
 
 groiindmass of quarlz and alblte. Plain light. 
 
Parti] GEOLOGY 17 
 
 gypsum zones in tlie southern part of the {rypsum belt. It is less than 
 10 feet thick and ean be traeetl for only two or three hundred feet. It is 
 composed of dark green, fine-grained rock that contains large lathlike 
 grains of hornblende in a finer grained matrix of biotite and oligoclase. 
 Chlorite is present — especially bordering hornblende grains — and there 
 are scattered anhedral grains of epidote. 
 
 (rypsu))i Bodies. Cypsum with other rocks occurs interbedded Avith 
 butf limestone in zones up to 100 feet thick that may be traced for 
 several thousand yards anil as less persistent, more lenslike bodies in the 
 green schistose rocks close to the limestone contact. Gypsum bodies, 
 except where they are exposed in cut banks or in artificial openings, are 
 concealed by a distinctive light-colored soft soil that forms rounded, 
 purt'y-looking hills and slopes. The relatively few exposures indicate that 
 although gypsum bodies as a whole are simple, yet they are complex in 
 detail. Gypsum, wherever exposed, is much the same and has similar 
 associations whether the body be in limestone or in schistose rock. 
 
 Connnonly less than half of a gypsum body is gypsum, sometimes in 
 beds 5 or 10 feet thick but more often a foot thick or less. Interlayered 
 with these beds may be a variety of materials. Green-colored schist is 
 almost always present, and quartzite may be found. Tremolitic limestone 
 is common. AVhite fine-grained sugary limestone is sometimes inter- 
 bedded w'ith gypsum. Some specimens of sugary limestone contain dis- 
 seminated anhedral gypsum grains, and some contain tremolite but less 
 than the brown tremolitic limestone described above. Chemical tests show 
 that some of the sugary limestone is dolomitic. 
 
 The gypsum itself is a coarse-grained aggregate of flaky, transparent 
 crystals up to -^^ inch in diameter. One specimen consists of large 
 euhedral to subhedral rectangular gypsum crystals ranging from 
 0.10 X O.O.'J inch to 0.01 x 0.005 inch in size in a much finer grained 
 matrix of intricately interlocking gypsum grains. Although there are 
 beds of pure gypsum 10 feet or more thick, much of it contains im- 
 purities. Gypsum grades into schist, and some impure gypsum contains 
 as much as 20 per cent calcite. Similarly there are gradations between 
 schist and tremolitic limestone. The best exposures are in the mine of the 
 Utah Construction Company which is described below. 
 
 Anhydrite, although not plentiful, has been found in the deepest part 
 of the Utah Construction Company quarry. Anhydrite in place was not 
 seen, but it occurs abundantly in the neighboring mines of the United 
 States Gypsum Company where it is believed to be the immediate source 
 of the gypsum. The anhydrite is a white material with a faint bluish tinge 
 most of which is the mineral anhydrite in grains 0.02 incli up to 0.20 inch 
 in size. A majority of the grains have polysynthetic twinning, many in 
 two directions. In the single specimen examined under the microscope 
 gypsum comprises 15 per cent of the total. Gyp.sum fills cracks 0.005 to 
 0.05 inch wide that follow anhydrite grain boundaries. Some anhydrite 
 grains that are completely surrounded by gypsum have the shape of the 
 anhydrite cleavage. All of the gypsum has a fibrous texture. Some of 
 the wider gypsum veinlets are composed of grains in which the fibers are 
 imperfectly aligned; such grains have the same shape as the anhydrite 
 grains. 
 
 3—58771 
 
18 GYPSUM IN CALIFORNIA [Bull. 163 
 
 Structure 
 
 The rocks of the gypsum belt have an average strike of N 70° E and 
 dip northwest at angles that increase from G0° at the south side to ver- 
 tical in the buff limestone on the north side. Farther north the dip 
 decreases to about 60° NW at the bounding fault. The presence of 
 gypsum zones and limestone beds on opposite sides of the central green 
 schistose rocks suggests that the entire gypsum belt may be an anticline 
 overturned and crowded against the north granite. Inconclusive evidence 
 that the axis passes through the central area is given by the prevailing 
 westerly dip of the green schistose rocks and by the attitudes of some 
 outlying outcrops of limestone and gypsum southwest of the quarry. It 
 is to be noted, however, that the succession of rocks on the south side of 
 the gypsum belt is not exactly the same as on the north side. In pai-- 
 ticular, on the south side there is no great thickness of quartzite nor is 
 there a counterpart to the limestone found between the quartzite and 
 the north granite. It is probable that the gypsum belt contains two groups 
 of gypsum zones that are similar but not identical. 
 
 Faulting is present but is relatively minor. The most prominent fault 
 is the nearly vertical one that separates the north granite from the 
 limestone. The fault, which is exposed in the larger canyons north of 
 the Utah Construction Company quarry, is a single sharp break nearly 
 free of gouge. A second fault, or probably fault zone, runs transversely 
 to the regional strike 3000 feet east of the Utah Construction Company 
 mine. Although its surface is nowhere exposed, the fault has offset the 
 limestone beds one to two hundred feet. There is no evidence of this fault 
 in the green schistose rocks. There are in addition other smaller trans- 
 verse faults that cut the limestone beds. 
 
 The Utah Construction Company Quarry (64) 
 
 The quarry of the Utah Construction Company is on a hill surrounded 
 by alluvium. Thick gypsum beds associated with schist are exposed liere, 
 but tliey are not readilv recognizable bevond the alluvium. Probablv thev 
 are a eomparatively local concentration of gypsum on the schist side of 
 the contact of the limestone with the green schistose rocks. 
 
 The mine workings (fig. 2) have encountered several thick layers of 
 gypsum with interbedded schist. The gypsum is the typically coarse- 
 grained material of high purity characteristic of the Little ]\Iaria Moun- 
 tains area. No great quantity of granular green feldspathic quartzite 
 occurs in the quarry, although there is some of the fine-grained, bloeky 
 feldsi)atliic quartzite. Most of the schist in the quarry is a bluish-gray 
 ([uartz-biotite schist that contains nnich less epidote and tremolite than 
 the granular feldspathic quartzite. The biotite schist found in the quarry 
 contains about 15 percent gypsum in the form of fibrous, slightly elongate 
 grains interlocked with the quartz grains. Perpendicular to the plane 
 of tile bedding gypsum is in comparatively sharp contact with schist, but 
 along the strike it grades into gypsum containing small schist lenses or 
 dis.seminated flakes of a green micaceous mineral. 
 
 One specimen of mixed gypsum and schist consists of gypsum mixed 
 with a minor amou)it of calcite in the form of lenses up to 3 in<'hes in 
 diameter and half an inch tliick separated by schistose layers up 1o a 
 quarter of an inch thick containing biotite, muscovite, and tremolite. 
 
I»art 11 
 
 GEOLOGY 
 
 19 
 
 -1 1 1 1 1 I II I I.I 1 1 1 1 1 1 
 
 EXPLANATION 
 
 ■Qal- 
 
 Alluvium and fill 
 
 Gypsum 
 
 Gypsum and schist 
 
 Schist 
 
 Limestone 
 
 Figure 2. Geologic map of the Utah Construction Company quarry, 
 Little Maria Mountains. 
 
 
 
 V) 
 
 3 
 
 m^ 
 
 o 
 
 
 a> 
 
 •5 
 
 nor«> 
 
 o 
 
 1 
 
 ^9s; 
 
 ^ 
 
 O 
 
 
 1,1,1,1,1 
 
 1 1 si 1 
 
 i 1 1 1 1 1 1 1 1 
 
 1 
 
 
 a. 
 
 Is 
 
 
 
 
 — ^ Contact 
 
 c 
 
 
 
 
 <n>TTr<' Bench 
 
 
 E 
 
 
 
 1 Attitude of beds 
 
 
 
 
 
 
 SCALE 
 
 :s 
 
 100 
 
 50 
 
 100 200 
 
 1 1 1 
 
20 GYPSUM IN CALIFORNIA [BuU. 163 
 
 These layers of impurities are curved around the gypsum lenses. Some 
 of the gypsum contains streaks of brownish calcite. A thin section of 
 such a specimen contains about 20 percent calcite in the form of anhedral 
 grains intricately interlocked with fibrous gypsum grains. Tremolitic 
 limestone occurs in the quarry, but it is almost entirely restricted to a 
 5-foot bed in the southeastern part. 
 
 The average trend of these alternating gypsum and schist layers is 
 N. 25° E. with a dip of about 60° NW. The strike in the quarry is thus 
 noticeably more northerly than the average of the Little Maria IMoun- 
 tains gypsum belt. Locally there is a wide departure from the average 
 trend in two parts of the quarry. In the southeastern part and north of 
 the crusher a mound of waste has been left unmined. The structure here 
 is a syncline plunging to the southwest. In the southwestern part there 
 is a nose projecting into the alluvium that may be a plunging anticline. 
 
 The quarry can be divided into several parts geologically. Immediatelj'' 
 southeast of the quarry is a hill of granular green feldspathic quartzite 
 and gypsiferous green schist similar to that which occupies the central 
 part of the gypsum belt beyond the alluvium to the east. Close to its base 
 on the northwest side there is a pod of tremolitic limestone that grades 
 into green schistose rock. The contact between the rocks of this hill and 
 the gypsum in the quarry is concealed by fill. In the southeastern part 
 of the quarry is the s.ynclinal mound mentioned above. Gypsum that 
 occurs around the flanks dips beneath a core of blocky green quartzite. A 
 bed of tremolitic limestone occurs in the quartzite close to the quartzite- 
 gypsum contact. 
 
 The central part of the quarry lies between the synclinal mound and a 
 bed of biotite schist. Most of it is in gypsum, but there are a few small, 
 scattered lenses of both schist and tremolitic limestone. Along the east 
 side of the quarry the gypsum was followed as much as 15 feet below the 
 alluvium, and it was reported that limestone was encountered in the 
 northern part of this excavation. Along the middle bench, where there are 
 good exposures, the gypsum contains a number of layers of mixed gypsum 
 and schist similar to those described above. 
 
 Farther northwest and lying between thick schist layers is a bed of 
 gypsum from 20 to 60 feet wide. Where it crossed the lower bench it is 
 quite narrow, but it widens northward. In the face of the upper bench 
 there is a GO-foot thickness of nearly pure gypsum between schist layers 
 that dip 60° NW. On the top of the bench, however, gypsum exists only 
 as lenticular bodies three feet thick or less mixed with gypsiferous schist. 
 Probably the gypsum grades into schist along the strike, and it may 
 plunge northeastward also. 
 
 The southwest nose consists of mixed gypsum and schist with a little 
 tremolitic limestone in which the proportion of gypsum ranges up to 75 
 percent. Attitudes of some lenses depart widely from the average of the 
 quarry and suggest that the nose may be anticlinal. 
 
 Along the northwest side of the quarry gypsum originall}' bordered 
 the wash. It has, however, been mined ; the excavation has been tilled. 
 
 Schistose rocks occur north of the quarry, and in the northeastern 
 part of the island hill, where the quarry is located, there is limestone 
 that dips beneath the schistose roeks. The trend of gypsum in the central 
 part of the quarry indicates that its extension lies beneath the alluvium 
 southeast of the northern part of the hill, but beyond the alluvium there 
 are no comparable gypsum bodies. 
 
Parti] GEOix)GY 21 
 
 Palen Mountains Deposits, Riverside County (69) 
 
 A larfre deposit of ^'ypsuiii associated with pre-Tcrtiary meta-scdiincn- 
 tarv and meta-i*rnoous rocks exists in tlie Palen Mountains in sections 
 2, 3, 4, 9, 10, and 11. T. 3 8.. IJ. 18 E.. SBM. The {rypsum occurs just 
 south of Granite (Palen) Pass, a low jit'diment pass of comparatively 
 moderate relief that separates the Palen Mountains to the south from the 
 (iranite IMountains to the north. The pass is 1| miles wide and 3 miles 
 lonpr. The deposit lies 20 miles northwest of Blythe and 30 miles northeast 
 of Desert Center, while the nearest railroad is 15 miles northeast at Rice, 
 a station on the Santa Pe's Parker hi-audi. The hest approach is from the 
 Desert Center-Vidal hi<rliway. from which 16.7 miles from Desert Center, 
 a road turns eastward toward Granite Pass. This seldom-traveled road is, 
 however, likely to he covered with dune sand. 
 
 Operations have been restricted to surface exploration and develop- 
 ment work. Diamond drilliiifr or other subsurface exploration has not 
 been undertaken. Extensive claims were patented 20 to 30 years afro by 
 John Webb and Georpre Pepperdine, and in 1040 John Webb and Fleet- 
 wood Lawton carried out some additional development. 
 
 The followinpr freolo<_nc summary of the deposits is based larjrely on 
 studies of R. A. Iloppin,^^ made primarily to reveal the internal structure 
 and petrology likely to be found in the mountain ranges of the Basin — 
 Ranges geomorphic province. E. C. Harder '- made a reconnaissance of 
 the area in 1909 and described the gypsum deposits in general terms. 
 
 Although the geology of the region is complex, the broader features are 
 relatively simple. The gypsum occurs in a series of meta-sediments that 
 includes marbles, quartzites. and thermal metamorphic derivatives of 
 them, lloppin has correlated this gypsum-bearing series with the ]\[aria 
 formation of Miller ^^ on the basis of lithology. North of these meta-sedi- 
 ments lie the granitic rocks of the Granite Mountains, and to the south 
 are meta-sediments that have been tentatively assigned to the ]\IcCoy 
 Mountains formation." In the area under consideration a sill-like body 
 of meta-igneous rock lias intruded the gypsum-bearing series. The meta- 
 sediments and meta-igneous rocks are arranged roughly in bands that 
 trend east-Avest across the range and dip predominantly to the north at 
 moderate angles. Five principal bands are di.stinguishable, which from 
 north to south are as follows : 
 
 1) Mota-scdiments, principally in tho northwe.^t part of the area. 
 
 2) Meta-igneons rock, extending about two-thirds of the way across the range from 
 west to east. 
 
 3) Meta-sediments. 
 
 4) Porphyrobhistic meta-igneous rock. 
 
 5) Meta-sediments. 
 
 Gypsum in quantities large enough to be of probable economic interest 
 is found in three places. The .southern gypsum-bearing series is in the 
 eastern end of band five, the northeastern gypsum-bearing series is in 
 the eastern end of band three, while the northwestern gypsum-bearing 
 
 " Hoppin, R. A., The geolopy of the Palen Mountains gypsum deposit. Riverside County, 
 California : Division of the Geological Sciences, California Institute of Technology, 
 Contribution No. 5S0, June 1951 (unpublished). 
 
 " Harder, E. C, The gypsum deposits of the Palen Mountains, Riverside County, Cali- 
 fornia : U. S. Geol. Survey, Bull. 430, pp. 407-416, 1910. 
 
 "Miller, W. J., Geology of the Palm Springs-Blvthe strip. Riverside County, California : 
 California Div. Mines, Rept. 40, p. 25, 1944. 
 
 " Miller, W. J., op. cit, p. 32. 
 
22 GYPSUM IN CALIFORNIA [Bull. 163 
 
 series is in band one. Each differs from the others in stratigraphic suc- 
 cession and is separated from the others by meta-igneous rocks. It is 
 assumed that the three are separate units of the gypsum-bearing series. 
 The following table summarizes the geologic history of the area. 
 
 1) Deposition of the j^ypsum-bearing series. 
 
 2) Deep burial followed by the onset of stresses resulting in the regional nieta- 
 niorphism of the sediments. 
 
 'S) Intense cataclastic deformation, including folding, faulting, breeciation, and 
 crushing. 
 
 4) Erosion followed by deposition and burial of McCoy Mountains ( ?) formation. 
 
 5) Intrusion of quartz diorite. 
 
 (>) Faulting and regional metamorphism — less severe than in (2). 
 
 7) Intense metasomatic activity including felspathization and rccrystallization 
 followed by intrusion of aplites and pegmatites, and finally by liydrot hernial 
 veins. 
 
 8) Erosion: deposition of Tertiary (?) or Pleistocene gi'avels, probably some 
 faulting. 
 
 9) Small-scale normal and reverse faulting. 
 
 10) Deposition of gravels. 
 
 11 ) Faulting of recent gravels. 
 
 Deformation lias been profound. The results of folding, faulting, 
 crushing, brecciation, shearing, and jointing are apparent and range 
 downward in size to the microscopic. Almost all contacts are fault con- 
 tacts. The most intense deformation occurred before the intrusion of the 
 igneous rocks, but the igneous rocks themselves have been notably de- 
 formed. 
 
 The igneous body was intrdued as an irregular sill. The south contact, 
 althougli modified by faulting, is fairly regular ; but the ]u)rth or hanging 
 wall contact is complex. Irregular apophyses 1 foot or 2 feet in diameter 
 and ramifying dikes and sills an inch thick or less cut the meta-sediments, 
 and within the large meta-igneous masses are to be found small, scattered 
 patches of the meta-sediments. In general the structure is more complex 
 in the western part of the area than in the eastern. A large area in the 
 western part of band three was not differentiated in mapping, and the 
 western two-thirds of band five was mapped as undifferentiated meta- 
 sediments. 
 
 Gypsum occurs in massive beds of high purity up to 100 feet thick that 
 are interbedded with marble and quartzites. Not only do the gypsum beds 
 change quickly in thickness along the strike, but they contain isolated 
 blocks and lenses of marble ranging up to several tens of feet thick. Less 
 common impurities are quartzite and fine-grained green schist containing 
 epidote, green biotite, chlorite, and quartz that may form thin green films 
 or occur as rock composed of alternating layers of gypsum and waste an 
 inch or two thick. 
 
 The gypsum itself is a white aggregate of anhedral grains whose aver- 
 age size is 0.2 millimeter. The microscoi>e reveals sparsely distributed 
 grains of calcite and epidote. Little anhydrite occurs on the surface, and 
 its presence at depth has not been ascertained. 
 
 The marbles are fine-grained rocks that are wliite to buff in color, or 
 less commonl.y, pink, dark brown, or gra.v. Dolomitic marble was not 
 found, although some of the marble that has been recrystallized by 
 thermal metamorphism contains magnesium minerals. The effects of the 
 intrusive body on the marble are discussed below. 
 
 Two principal types of quartzite are recognized. The first, consisting 
 mainly of quartz with a minor amount of white mica and hematite, is 
 
Part 1 ] GEOLOGY 23 
 
 Avliite or pink. The sol-oiuI is a j^roi'ii (|iiai-t/.ite ctontaiiiiu;^ »iiiai-t/. Icldspar, 
 ('l)i(l()t('. and treinolitc that sliows jji-cIVitihI oriental ion. The <iuartzites 
 oeeur as tliiek beds cut by closely spaced joints, as narrow partinjrs in 
 jryi)sir('i'<ins beds, and as laminated, incompetently folded calcareous 
 (|uartzite alternatinji: with marble. Closely associated with the (jnartzites 
 are the {.n-its. a ^^roup of rocks in wiiich ^n-ains of feldspar and quartz 0.2 
 In ()..'! millimeter in size occur in a much finer matri.x of these and otiier 
 minerals. The j.'rits ^rade into (Hpiiirranular (juai't/.ile. 
 
 The meta-i<rne()us rocks retain little of their ori^nnal igneous textures. 
 They are now strouirly foliated, fiiu'-p:rained biotite-epidotc-albite-(piartz 
 schist. The chemical composition and the ))resence of relict andesiiie sug- 
 jrest that the intrusive nuiy liave been ori<:inal1y diorite or quai'tz diorite. 
 
 The etfect of the intrusive on the j>ypsum isdiflicult to evaluate because 
 no intrusive contacts are exposed. It is assumed that dehydration was 
 the oidy etfect. In the marbles, however, the intrusive produced skarns 
 of <rarnet, epidote, and amphibole, and caused zones of recrystallization. 
 Trending' east-west across the an'a aiul l>in<jr directly above the meta- 
 {•rneous sill are dense, fine-grained, white, lime-silicate rocks that form a 
 series of sharp peaks. They are composed of calcite with subordinate 
 amounts of wollastonite, diopside, and epidote. 
 
 A i)ost-intrusion pei'iod of regional metamoi'])hism is postulated be- 
 cause the meta-igneous rocks cut off all the folds and the uuijor faults in 
 I he meta-sedimeuts. ]t is suggested that the post-intrusion metamorphism 
 was less severe than the pre-iutrusion metamorphism. 
 
 The metasomatic and hydrothermal activity that followed the second 
 |)eriod of regional metamorphism resulted primarily- in the feldspathi- 
 zation of the meta-igneous rocks. The southern third of the intrusive body 
 contains abundant feldspar porphyroblasts ; and the porphyroblastie 
 phase, although retaining its orientation, is granitic in appearance. Zones 
 of incipient feldspathization are to be found within the non-porphyi'o- 
 hlastic phase. The last stage of the mineralization is represented by veins 
 and mineralized sheer zones that cut both the meta-sedimentary and 
 meta-igneous rocks. Possibly the hydrothernuil activity is associated with 
 the emplacement of the granitic rocks of the (iranite ^Mountains. 
 
 The gypsum, Iloppin believes, was originally formed through sedi- 
 mentary processes of deposition. Although the relations of the gypsum 
 to the enclosing marble and (juai-tzite have been greatly modified by 
 tectonic agencies, several areas suggest that the original sediments in- 
 cluded zones in which thin limestone beds interfingered with thin gypsum 
 beds. The absence of associated salt beds and the presence of interbedded 
 gypsum and limestone suggests that the calcium sulfate preci]ntated from 
 brine of comparatively low salinity. It is likely, therefore, that most of the 
 calcium sulfate origiiuUly precipitated as gypsum.^'* 
 
 The sedimentary gypsum was converted to anhydrite during the pre- 
 iutrusion period of regional metamorphism. Heat is believed to be the 
 controlling factor in the conversion of gypsum to anhydrite. Subsequent 
 erosion has expensed the anhydrite and permitted gypsum to form again. 
 The eflf'eet of the post-intrusion period of regional metamorphism is open 
 to question, for Hoppin doubts that a suflficiently high temjierature was 
 attaiiKMl to dehydrate the gy])sum. The presence of deformation fabrics 
 
 '■'^ Pusjnak, E.. Deposition of calcium sulfate from sea water: Am. Jour. Sci., vol. 238, 
 pp. 5G5, 566, 1940. 
 
24 GYPSUM IN CALIFORNIA [Bull. 163 
 
 in the gypsum suggests that the gypsum itself has been deformed because 
 it is doubtful that deformation fabrics in anhydrite could survive hydra- 
 tion and its accompanying volume change. The isolated marble blocks that 
 occur in the gypsum apparently have been jostled about, and this fact 
 further supports the theory that the calcium sulfate existed as gypsum 
 during the deformation. 
 
 Riverside Mountains Deposits, Riverside County (70, 71) 
 
 A large deposit of pre-Tertiary gypsum occurs on the east face of the 
 Riverside Mountains about four miles south of Vidal in the northwest 
 corner of T. 2 S., R. 24 E., SBM. Part of the gypsum is in the (\)lorado 
 Indian Reservation. Development work only consisting of short tunnels 
 and test pits has been carried out. No road goes to the deposit. An aban- 
 doned road leaves U. S. Highway 95 four miles south of the San Bernar- 
 dino County line and crosses the alluvial fan to an old camp at the mouth 
 of the principal canyon along this part of the mountain front. A trail con- 
 tinues up the canyon. The principal gypsum deposit is on a south branch 
 of the main canyon. Its mouth, which is very inconspicuous from the 
 bottom of the main canyon, was marked in 1949 by two lengths of stove 
 pipe strung on a pole. Relief is extreme, and the construction of a road 
 would be difficult. 
 
 Maria (?) fm 
 pre— Creloceous 
 
 Vim Limestone O 
 
 SECTION THROUGH THE RIVERSIDE MOUNTAINS DEPOSIT 
 
 Figure 3. 
 
 Gypsum occurs in a 100-foot zone that dips southwest at angles of 50° 
 or greater and strikes northwestward. The zone is made up of coarsely 
 crystalline white gypsum interbedded with brown-weathering crystalline 
 limestone and red quartzite. Between the gypsum zone and the highway 
 are quartz-biotite schist and several hundred feet of limestone. The gyp- 
 sum crops out for at least half a mile. Lying on the hanging wall limestone 
 is several hundred feet of gypsiferous green schist that has been briefly 
 described by Noble. ^*^ The schist is cut by quartz veins, and it also contains 
 a few lenses of crystalline gypsum up to an inch thick. Gypsite up to 10 
 feet thick covers the green schist. 
 
 Clark Mountain Area, San Bernardino County 
 Undeveloped deposits of gypsum occur in the northeast corner of San 
 Bernardino County, north of Clark j\Iountain at the south end of Mes- 
 quite Valley. They are associated with pre-Cretaceous sediments that, un- 
 like those of the gypsum deposits of eastern Riverside County, are not 
 noticeably metamorphosed. 
 
 "Noble, Li. F., Nitrate deposits in southeastern California: U. S. Geol. Survey Bull. 820, 
 pp. 49-52, 1931. 
 
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 PHOTOMICROGRAPH OP IMPURE GYPSUM 
 Containing calcite and tremolite, Little Maria Mountains. Plain light. 
 
DIVISION OF MINES 
 
 BULLETIN 163, PLATE 18 
 
 DETAIL OF SCHIST AND GYPSUM 
 
 Northwest corner of the Utah Construction Company quarry coarsely crystalline gypsum 
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 containing epidote and tremolite. 
 

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Parti] 
 
 GEOLOGY 
 
 25 
 
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 Figure 4. Index map sliowing looatiijii of Shire gypsum deposit. 
 
 5—58771 
 
26 
 
 GYPSUM IN CALIFORNIA 
 
 [Bull. 163 
 
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Part 1 ] GEOLOGY 27 
 
 Shire Deposit (87). D. II. Sliiro owns oi^rlit iiiiiiatonted claim.s esti- 
 mated to be ill see. 5, T. 17 N., K. 14 E., SILM. that were loealed in 194(3. 
 Ill 1951 the property could be reached from Sandy on tlie Valley Wells- 
 (ioodsprinj,'s road by following the old State Line Pass road for 11.2 miles 
 southeast to the end of Mescpiite Valley. A track passable for vehicles 
 and marked by signs leads from tiie State Line Pass road to the property. 
 The distance from U. S. Iliglnvay 91 and the Union Pacific Kail road via 
 the State Line Pass road, which is washed out, is 12 to 13 miles. Assess- 
 ment work only has been carried out on the property. 
 
 Two or more gypsum beds crop out for 1 to 2 miles along a large wash 
 that trends about N. 40" W. ]\Iost of the gypsum is low on the talus- 
 covered southwest side of the wash. Exposures of gypsum are scarce, 
 although large areas of probable gypsum are covered by only from a few 
 inches to a few feet of gravel. The deposit has been opened by a number 
 of shallow trenches, but additional development work is needed to reveal 
 fully the character of the deposit. 
 
 The general nature of the gypsum deposit is illustrated by the two large 
 scale sections (fig. 5) that accompany this repoi-f. The gypsum-bearing 
 beds strike about X. 40° \V. parallel to the wash and dip about 50° Sw" 
 Beds of gypsum more than 50 feet thick occur with sediments that 
 include black, thin-bedded, cherty limestone, tan-colored sandy limestone, 
 and brown shale. The thickest gypsum beds occur close to the wash and 
 quite possibly beneath the wash itself. Upward the proportion of gypsum 
 to limestone and .shale becomes increasingly less. The gypsum-bearing beds 
 are members of the Kaibab formation of Permian age.^^ Overlying the 
 g3'psum-bearing beds are 100 to .'300 feet of non-gypsiferons. red sand- 
 stone and shale of the ]\Ioenkopi formation (Triassic). The Kaibab beds 
 and the Moenkopi beds are in contact with Paleozoic limestones along 
 faults that i)arallel the wash. 
 
 The gypsum itself is a sugary whit(^ aggregate of glassy clear flaky 
 crj^stals about 0.01 inch in diameter. Some of the gypsum contains streaks 
 0.1 inch thick and half an inch to an inch apart of brown earthy matter 
 that contains calcite. Impure gypsum is to be found that consists of gyp- 
 sum alternating with tan-colored sandy shale in irregular laj^ers an inch 
 to 2 inches thick. 
 
 TERTIARY DEPOSITS 
 
 Rock gypsum deposits of Tertiary age range in size from thin, discon- 
 t iiiuous beds that are of no commercial interest except as a possible source 
 of gypsite to bodies containing many thousands of tons of nearly pure 
 gypsum. The largest gypsum mine in the state, the United States Gypsum 
 Company Fish Creek [Mountains operations. Imperial County, is in a 
 Tertiary deposit. Other Tertiary deposits are to be found in the Upper 
 Cuyama Valley region, Santa I>arbara and Ventura Counties; in the 
 Death Valley recrion. Inyo County; San Benito County; and in i\Iiocene 
 rocks of western Santa Barbara County. The California Tertiary deposits 
 are typically enclosed in shale associated with coarse-grained non-marine 
 sediments that have been mildly folded. The gypsum is a fine-grained, 
 compact material tb.at ranges from alabaster through dark gypsum to 
 gypsiferous clay. 
 
 " Howett, D. P., personal comniunication. 
 
28 
 
 GYPSUJI IX CALIFORXIA 
 
 [Bull. 163 
 
 CARRIZO 
 
 T. 13 S. 
 T. I4S 
 
 R.8E' R.9E. 
 
 1. Edward B. Roberts et q\ 
 
 2. Hillcrest Placer ^ 
 
 3. Gypsum King Placer* 
 
 4. Tract 68 * 
 
 5. Tract 67 
 
 6. El Centre Placer * 
 
 7. Tract 69 * 
 
 8. Gypsum Queen Placer * 
 
 9. Tract 70 * 
 10. Tract 72 
 
 II. Tract 71 
 
 12. Sylvester Kipp 
 
 13. Blanc Placer 
 
 14. Swallow Placer No.2 ^ 
 
 15. Swallow Placer * 
 
 16. Regent Placer* 
 17 Tract 78 * 
 
 18. Blanc Placer No 3 
 
 19. South Pole Placer * 
 20. W.H. Waters 
 
 FiGURR 6. Index map showing locations of gypsum claims in the Fish Creek Mountaims. 
 * Indicates United States gypsum claims. 
 
Parti J GEOLOGY 29 
 
 Fish Creek Mountains Deposit, Imperial and San Diego Counties 
 
 The United States Gypsum Comiiaiiy owns 12 patented claims (28) 
 near tiie northwest end of tlio Fish Creels Mountains that include parts 
 of sees. 19, 20, 28, 29, 80, 32, and 83, T. 13 «., R. 9 E., SBM. The principal 
 mininf? operations are in Tract G8 near tlie northwest end of tiie prop- 
 erty. In addition the California Portland Cement Company owns Tract 
 67 (25) in SWi sec. 19 and NW] of sec. 30, T. 13 S., R. 9 E., the Blue 
 Diamond Corporation owns Tract 71 (26) in SE\ NE| and NE] SE.i 
 sec. 29, T. 13 !S., R. 9 E., and the National Gypsum Company owns de- 
 posits (90) in sees. 3, 5, and 9, T. 13 S., R. 8 E., SBM. The Roberts and 
 Peeler strontium deposit (91) lies in sec. 13, T. 13 S., R. 8 E., SBM. 
 northwest of the ])riiu'ipa] <rypsum deposits. The strontium, which is 
 associated with gypsum, was last worked by the Pan Chemical Company 
 from 1940 to 1946. 
 
 The accompanying geologic map (pi. 20) covers an area in T. 13 and 
 14 S.. R. 9 E., SBM. about 30 miles west of Brawley. The western 
 boundary of Imperial County passes through the western part of the 
 mapped area. The area may be reached over a secondary road from 
 Scotty's Ocatilla on State Highway 78, 22 miles from its junction with 
 IJ. S. Highway 99 and 3 miles west of the San Diego County line. This 
 road, rough but passable for heavy ecpiipment, runs southeastward for 
 9 miles to the United States Gypsum Company's quarry. In addition, 
 a private narroAv gage railroad runs to the United States Gypsum Com- 
 pany 's calcining plant at Plaster City (29), about 25 miles to the south. 
 
 Tlie area mapped includes the low northwestern end of the Fish Creek 
 ^Mountains and extends westward to Fish Creek Canyon. Between the 
 hills east of Fish Creek Canyon and the Fish Creek Mountains is a broad 
 wash running S. 40° E. for about 4 miles from the northwest end of the 
 Vis]\ Creek Mountains. Gypsum crops out extensively on the hills border- 
 ing this wash, and large deposits oi: gypsum only partially exj^lored lie 
 outside of the wash and beyond the limits of the area mapped. 
 
 No detailed geologic descriptions of the area have been published, but 
 T. W. Dibblee, Jr. has furnished tlie author with an unpublished geologic 
 nmp of the Split IMonntain area, scale 1/62500, i)repared in 1944. In this 
 report Dibblee 's formation names have been adopted. Mining operations 
 in the area have been described in reports of the California Division 
 of Mines. ^^ 
 
 Stratigraphy 
 
 The oldest rocks in the area arc a i)re-Tertiary complex that includes a 
 series of metamorphic rocks intruded by plutonic bodies. The metamor- 
 phic rocks, which occupy perhaps half of the area mapped as basement, 
 are in most places represented by a well-foliated, coarse-grained gneiss. 
 In addition they include a body of coarse, blue-gray marble that was 
 mapped separately and minor amounts of mica schist and quartzite. The 
 structural trend of these rocks is N. 30° W. with dips of from 60° to 
 70° NE. 
 
 The most abundant of the plutonic rocks is a coarse-grained gneissic 
 granite in which foliation is moderately well-developed. The approximate 
 
 18 Sampson, R. J., and Tucker, W. B., Mineral resources of Imperial County : Calif. Div. 
 of Mines Rept. 38, pp. 134-136, 143, 1942. 
 Tucker, W. B., Imperial County: California State Min. Bur. Rept. 22, pp. 270-275, 284, 
 
 1 Q 9 P 
 
 Merrill. P. J. H., Imperial County: California State Min. Bur. Rept. 14, pp. 738-740, 
 1916. 
 
30 OYPSTTM IN CALIFORNIA [Bull. 163 
 
 composition is (luartz 40 percent, orthoclase 40 percent, plagioclase 5 per- 
 cent, biotite 15 percent, and a little chlorite. Grain size is from | to i 
 inch. This granite is deeply weathered and in some areas, particularly in 
 the northern part of the outcrop on the southwest side of tlie Avasli, it is 
 stained red by oxidized iron minerals. The g-neissic granite is cut by 
 pegmatite dikes up to 6 inches thick that contain coarsely crystalline 
 quartz and feldspar. 
 
 Associated with the granite is a plagioclase-biotitc rock in which biotite 
 flakes about 0.05 inch in diameter are oriented but not segregated into 
 layers. Biotite makes up about 40 per cent of the rock, while the remainder 
 is anhedral plagioclase, partly as grains the size of the biotite flakes and 
 partly as grains up to a quarter of an inch in size. The plagioclase-biotitc 
 rock occurs as inclusions in the granite, in dikelike bodies cutting the 
 granite, and as irregular bodies several hundred feet in diameter, 
 
 SiJlit Mountain Formation. The Split Mountain formation of Miocene 
 age is the oldest of the sedimentary rocks in the area and lies with deposi- 
 tional contact on the basement rocks. It is composed of poorly consoli- 
 dated, terrestrial sandstone and very coarse-grained conglomerate. In 
 the area mapped this formation may be divided conveniently into a lower 
 member that is noticeably red and an upper member that is gray. The 
 conglomerate beds strongly resemble the younger fans and can be distin- 
 guished from fans only by their topographift position. 
 
 The red member of the Split Mountain formation, which occurs only on 
 the southwest side of the wash, is well exposed in Fish Creek Canyon and 
 in the hills southwest of the wash. The base is exjiosed south of the prin- 
 cipal gypsum body on the southwest side of the wash where sandstone 
 lies with depositional contact on weathered granite. The lowest 50 feet of 
 the Split Mountain formation is a porous, very poorly cemented arkose 
 that is not red. Grains are well sorted and about an eighth of an inch in 
 diameter. Quartz predominates, but weathered feldspar grains containing 
 biotite flakes are present. 
 
 The remainder of the red member consists of red sandstone and con- 
 glomerate beds at least 850 feet thick. The sandstone, which is moderately 
 well cemented by calcite and much less porous than the basal beds, is 
 composed of angular, poorly sorted grains ranging from 0.1 to 0.5 incii 
 in size. The red sandstone also is made mostly of quartz grains, but feld- 
 spar that is present forms many of the larger fragments. Biotite is pres- 
 ent also. These beds are stained faintly red by oxidized iron minerals. 
 
 The lower part of the red member is predominantly sandstone contain- 
 ing a few thin lenses of conglomerate. By an increase in the number and 
 thickness of these lenses the saiulstone grades into a coarse-grained con- 
 glomerate of angular cobbles set in a shaly red matrix. The cobbles, which 
 have an average maximum diameter of 3 feet and locally reach 10 feet 
 or more in size, are composed of igneous and metamorphic rocks, princi- 
 pally gneiss and granite. 
 
 The gray member of the Split IMountain formation is predominantly 
 a conglomerate like that in the red member except that it contains no red 
 cement. The contact between the two is concealed beneath a loose cover 
 of boulders everywhere except near the mouth of Fish Creek Canyon. 
 Here it is sharp and conformable. The gray member contains lenses of 
 unconsolidated arkosic sandstone, and sand predominates near the top of 
 the formation. These uppermost sandstone beds contain layers of greenish 
 
Part 1 ] GEOLOGY 31 
 
 clay shale, and in many places near tin- lop a 1- or 2-foot bed of red-brown 
 sandstone is present. 
 
 The {?ray nienibor crops out )icar the mouth of Fish Creek Canyon and 
 extends eastward to the wash. It also foi-ms the extreme northwest end 
 of the Fisli Creek ^Mountains. To the southeast the red member is absent, 
 and the gray member lies directly on the basement. Here the basal beds 
 are akosic sandstone. Tn the southeast corner of the wash the Split IMonn- 
 tain formation is represented ])y as little as 20 feet of arkose, and there 
 is no conglomerate present. 
 
 Gypanm. liyinp: conformal)ly on the gray member of the Split Moun- 
 tain formation is at least 100 feet of nearly pure, massive gypsum. The 
 Itasal 10 or 15 feet of the gypsum commonly contains beds of sandstone or 
 sliale, but elastic impurities were not found in the main body. Similarly, 
 near the top the gypsum contains iuterbedded clastic material and grades 
 into the overlying formation. Tiie gypsum deposits are more fully de- 
 scribed below. 
 
 Imperial Formation. The Imperial formation (Miocene), which over- 
 lies the gypsum, consists of marine shale and poorly consolidated orange- 
 colored sandstone. Tn much of the area the beds have been removed by 
 erosion, but large areas in the southwest part of the wash have been ex- 
 posed where a covering of recent fans has been partly removed. A second 
 area where the Imperial fonnation is exposed is at the north edge of the 
 hills between the wash and Fish Creek Canyon. 
 
 Tlie contact with the gypsum is gradational. Tn the northern exposure 
 gypsum containing layers of greenish shale up to half an inch thick is 
 overlain by 5 feet of arkosic sand typical of the Split Mountain formation. 
 The arkose is overlain by about 100 feet of coarse, gray-green arkosic 
 sandstone that is brown when Aveathered. This sandstone, in contrast to 
 the gray arkose found beneath the gypsum, readily splits into slabs abont 
 half an inch thick. Perhaps it, as well as the gypsum, should be inelnded 
 in the Split I\Tountain formation. 
 
 Overlying the fissile sandstone are orange-colored sandstone beds alter- 
 nating witii beds of poorly consolidated, greenish clay shale. The sand- 
 stone consists of well sorted, subronnded quartz grains abont 0.01 inch in 
 diameter and a minor proportion of tiny biotite flakes. The grains are 
 heavily coated with and cemented by limonite and calcite. 
 
 Overlap. The Split IMountain formation, as suggested above, pinches 
 out to the southeast. Tn Fish Creek Canyon a thickness of 850 feet of the 
 red member alone exi.sts above the wash level. Tn the prominent cliff near 
 the county boundary, at the foot of which the basement rocks are exposed, 
 over 100 feet of the gray member lies on some 500 feet of the red member, 
 making a total thickness of only GOO feet. The red member does not appear 
 east of the wash. The gray member is as much as 800 feet thick southeast 
 of the ITnited States Gypsum Company's quarry and thins to a mere 20- 
 foot thickness of sand in the extreme southeast corner of the wash. The 
 gray member apparently thins northwestward also; it is only about 500 
 feet thick at the northwest end of the Fish Creek :\rountains. 
 
 The evidence of the original distribution of gyp.sum has been almost 
 entirely removed by erosion. At the north edge of the hills between the 
 wash and Fish Creek Canvon, however, it is but little more than 100 feet 
 
32 GYPSUM IN CALIFORNIA [BuU. 163 
 
 thick ; it pinches out entirely between gray sands of the Split Mountain 
 formation within 2000 feet of the county line. Seemingly the low point of 
 the basin shifted during tlie formation of these terrestrial and saline 
 deposits. 
 
 Structure 
 
 The principal structural feature in the area mapped is an open syn- 
 eline bounded by longitudinal faults. The axis of this syncline lies in the 
 wash. Although there is modification by local folding, dips are toward 
 the axis at angles of about 30° or less. 
 
 'i'he fault that bounds the synclinal basin on the northeast is along the 
 northeast side of the Fish Creek Mountains near the edge of the area 
 mapped. For most of its length it cuts basement rocks, but at its north- 
 west end basement rocks are in fault contact wath the Split Mountain 
 formation and also with a snuiU outcrop of gypsum. 
 
 The principal fault in the area is a steeply dipping fault that separates 
 the basement from the sedimentary rocks along much of the southwest 
 side of the wash. Tn a few exposures the fault appears as a zone of breccia 
 and gouge up to 50 feet in width. The fault zone is exposed near the 
 mouths of the canyons south of the gypsum body on the southwest side 
 of the wash and also high on the fan in the southwest corner of the wash. 
 Two small hills of gypsum at tlie foot of the steep slope of basement rocks 
 are further indirect evidence of the location of the fault zone. 
 
 West of the fault the Split Mountain formation has been folded into a 
 gentle anticline that approximately parallels the syncline in the wash. 
 The northeast limb has been eroded off, leaving the basement rocks 
 exposed. 
 
 On the major structural features minor folds have been superimposed. 
 Such a fold exists near the United States Gypsum Company's quarry 
 where a great thickness of gypsum has been folded into a northeast-trend- 
 ing trough. A com])lemcntary anticline has brought the gray conglom- 
 erate close to the surface on the southeast, and northwest of the trough 
 there is no great quantity of gypsum for about a mile. Similar minor 
 structures probably account for attitudes that depart from the regional 
 trend in the southwestern exposure of the Imperial formation. 
 
 Still smaller structures exist in the gypsum that do not involve the 
 underlying formation appreciably. Where the base of the gypsum is ex- 
 posed in canyons it dips uniformly for distances of as much as ]000 feet. 
 The overlying gypsum is, however, characteristically coutoi'ted. Ninety- 
 degree changes in strike and dip within 10 yards are common. 
 
 Gypsum Deposits 
 
 The existing gypsum deposits are remnants of a formerly thick bed 
 that probably covered a much larger area than that ma]iped. The largest 
 and thickest remnants are in the nortliAvestcrn half of the United States 
 Gj^psum Company's ]n-oi)erty. To the southeast erosion has separated 
 the gypsum into detached bodies. The gypsum on the northeast side of 
 the wash dips beneath the aluvium and reappears on the other side. Some 
 small outcrops indicate that the gypsum exists beneath the large body 
 of the Imperial formation that crops out in the southeastern part of the 
 wash. Another large remnant lies above the cliff near the county bound- 
 ary, and a 100 foot thickness of gypsum occurs on the Roberts and Peeler 
 property. One small remnant indicates that the gypsum once covered the 
 conglomerate that forms the northwest end of the Fish Creek Mountains. 
 
I 'art 1 1 GEOi-oov 33 
 
 Siu-fjK'c cxposiiiv^s '_Mv<> littlo cvifloin'o of tltf niMxiiinini tliiokncss of tlio 
 j:yj)suiii. ]\Iinin^' operations in tlii^ Ignited States (iypsuni f'onipaiiy's 
 quarry have disclosod over 100 tVet of frypsnm above the wasli level, and 
 tli(M-e is no indication of how much deeper it may pro. It has already been 
 mentioned that the irypsnm in this area has been down folded into a 
 troujrh and that the base here is unusually irre<rular. Perhaps, for the 
 area maj^ped. TOO feet is the averapre maximum thickness of prypsum 
 remainiuir above the wash level. In the two small areas where the original 
 thickness has been preserved and is exposed, the prypsum is 100 feet 
 thick or less. 
 
 At the base the <ry psuni jirades into the prray member of the Split ^loun- 
 tain formation. Excellent exposures of the base may be seen in the can- 
 yons that cut the jrypsmn on both sides of the wash and it ma}' also be 
 seen in the T'nited States fiypsum Company's workinprs on both sides 
 of the thick prypsum ref(>rred to above. Always p:ray arkose immediat(dy 
 underlies the prypsum. Toward the southeast there may be 10 feet or more 
 of arkose. but in the northwestern exposures there is likely to be only 
 an inch or two of arkose separatinp: the pypsum from the conprronierate. 
 The lowest beds of the "ryjisum contain interbedded prypsiferous sand oi- 
 shale. At the base of the irypsum on the southwest side of the wash a 30 
 foot bed of prypsum lies as much as 50 feet beloAV the main body, but at 
 most places the interbedded sand is only a foot or two thick or at the 
 most, four feet. 
 
 The prypsum itself is a compact, equipfranular, fine- to medium-grained 
 material with a prrayish tinpre. Thin, vapfue, brownish bands are visible in 
 the hand specimen. The microscope shows that the apparently equigranu- 
 lar gypsum has been lai-i;ely recrystallized into tiny fibers. The prypsum 
 is divided into areas in which the {ryjisum fillers arc aliprned or nearly so, 
 and this feature undoubtedly is responsible for the prranular appearance 
 of the hand specimens. Here and there may be seen anhedral prypsum 
 p-rains that are not fibrous. Tiny detrital shreds of biotitc exhibitinp: 
 prreen pleochroism are uniformly but sparsely distributed. Finely divided 
 opaque matter, perhajis a mixture of iron and manpranese oxides, is pres- 
 ent and is concentrated to some extent along grain boundaries. 
 
 The basal 5 to 10 f^et of the gypsum, particularly in the northwestern 
 part of the Ignited States (lypsum Company's ]n-opert3', contains a sooty, 
 black material that chemical tests indicate to be mixed oxides of man- 
 ganese and iron. "White gypsum comprises 60 percent of these beds; the 
 remainder is impregnated with the black matter. Ellipsoidal bodies of 
 white gj'psum up to ^ inch long are mixed with the black, and thin black 
 films occur along the bomidarics between the white bodies. Usually there 
 is a crude banding. Close to the surface the black matter has been changed 
 to a brick red color. 
 
 Selenite in the form of glass-clear .sheets half an inch to 2 inches thick 
 occurs at a few widely separated spots. At these places selenite is inter- 
 bedded with greenish shale close to the base of the gyp.sum. Selenite also 
 occurs within the gypsum body. 
 
 Gypsum forms smoothly rounded hills covered -svitli brown gypsif erous 
 soil. Beneath the soil lies 5 to 10 feet of leached and porous gypsum. 
 Gullies are deeply incised, narrow, and steep-walled. Gj'psum is more 
 resistant to erosion than are the underlving arkose and conglomerate. 
 
34 GYPSUI^r IN CALIFORNIA [Bull. 168 
 
 Anhydrite. Anhydrite was not found on the surface, but it does occur 
 in the United States Gypsum Company's quarry about 120 feet vertically 
 below the crest of the face. The anhydrite is a fine-prained white rock 
 with a faintly bluish-gray tinge. In thin section anhydrite is seen to be 
 a felted mass of fibrous crystals that have no preferred orientation. The 
 fibers are grouped in knots, and some fibers are arranged in bending and 
 I'adiating groups. Some knots contains fibers up to 10 times th(> average 
 size, and here and there may be found blocky cleavage fragments of 
 anhydrite. Like gypsum, anhydrite is clouded with opaque finely divided 
 matter that is concentrated to some extent along grain boundaries. 
 
 All the specimens of anhydrite observed have been replaced to some 
 extent by gypsum. Where anhydrite occurs in the (piarry, anhydrite-rich 
 beds alternate with beds that are mostly gypsum. The gypsum-rich beds 
 contain subangular masses of anhydrite an inch or two inches in diam- 
 eter, and these masses are cut by branching threads of gypsum. In the 
 anhydrite-riL'h beds 1-inch thick layers of gypsum contain lenses of 
 anhydrite g-iuch in size. The microscope shows that no anhydrite is com- 
 pletely free of gypsum and also that even the highest grade of gypsum 
 quarried contains a small amount of anliydrite. 
 
 Thin sections of mixed gypsum and anhydrite show that the anhydrite 
 grain size is smallest at anhydrite-gypsum boundaries and increases 
 toward the centers of anhydrite bodies. Gypsum in close proximity to 
 anhydrite does not have the fibrous character already described. Gypsum 
 closely associated with anhydrite is in the form of anhedi-al grains that 
 do not have a sharp extinction angle. Along boundaries gypsum pene- 
 trates far into anhydrite. "Within anliydrite bodies gypsum maj' be hardly 
 more than gypsiferous areas filled with anhj-drite fibers. Occasionally 
 gypsum may penetrate anhedral crystals of anhydrite along a rectangu- 
 lar pattern like the anhydrite cleavage. 
 
 Away from anhydrite gypsum may be as anhedral grains with a 
 sharper extinction angle than the vague areas described above. Most of 
 them contain corroded anhydrite inclusions. T^sually, liowever, gypsum 
 is fibrous, and the farther from anhydrite the finer are the fibers and the 
 more perfect is their alignment within grains. 
 
 Satin spar veinlets up to -^-inch wide cut both gypsum ami anhydrite. 
 T'.sually they are composed of lath-shaped gypsum crystals that are ori- 
 ented normal to the veinlet walls. These crystals have a sharp extinction. 
 Anhydrite remnants are to be found within these crystals. Veinlets walls, 
 although straight, are irregular in detail. One vein-shaped body of gyp- 
 sum cutting anhydrite is made up of fibrous gypsum in which there are 
 suggestions of grains arranged like the pattern in the satin spar veinlets. 
 
 The evidence suggests that replacement of anhydrite by gypsum began 
 along fractures and proceeded until varying proportions of anhydrite 
 were left as partly rounded remnants. Not enough exposures of anhy- 
 drite were found to determine whether a relation exists between depth 
 and the presence of anhydrite. Tt is probable, however, that calcium 
 sulfate, wherever it is buried to a depth of 100 to 150 feet, exists as 
 anhydrite. 
 
 Celestite. Celestite was found only on the Roberts and Peeler prop- 
 erty, although specimens of strontium-bearing gypsum in the possession 
 of the United States Gypsum Company are thought to have come from 
 
ViiVt 1 ] GEOLOGY 35 
 
 tlu'ir property. Celestite forms a disset-ted cap ahoiit 10 feet thick on a 
 liill composed of about 100 feet of gypsum lyintf on jjray conjrlomerate. 
 There is no indication that celestite occurs at the original top of the 
 l^ypsum liore. 
 
 Two small open cuts have been made in the celestite in addition to the 
 natural outcrops. At one place gypsum is interbedded with the celestite, 
 and in another place the celestite immediately overlying the gypsum is 
 in th<' form of siihanguhir nodules up to 6 inches in diameter. The celes- 
 tite clearly is conformal)k' with the underlying gypsum and ])robal)ly 
 is a lens. 
 
 The celestite is faintly bluish when fresh, but Aveathered surfaces are 
 brown and .jagged. The I'ock is composed of a fine- to medium-grained 
 porous mass of anhedral celestite grains with very finely divided calcite 
 grains conceiitrated along the celestite crystal boundaries. Black oxides 
 are present also. Although most of the celestite crystals are granidar, 
 elongate crystals and radiating groups of crystals are to be found. 
 
 Quatal Canyon Deposit, Ventura County 
 
 A comparative ne\V(H)mer among California's gypsum producing areas 
 is the northwestern corner of \\'ntura County. Gypsum occurs about 5 
 miles east of Ventucopa, a post office and store on U. S. Highway 399 in 
 I lie upper part of the Cuyama Valley. The deposit consists of a single 
 bed from 10 to 30 feet thick that occurs in mildly folded Tei-tiai-y rocks. 
 The outcrop of this bed may be traced for at least 7 miles between iJal- 
 linger Canyon and Quatal Canyon. 
 
 The principal mining operation is that of the Monolith Portland 
 Cement Company which supplies the gypsum requirements of the port- 
 land cement plant at Tehacha})i. The Monolith propertv (109) lies in 
 sees. 18 and 19, T. 9 N., R. 23 W.. and sec. 24, T. 9 X., R. 24 W., SBM. 
 in a branch canyon north of Quatal Canyon. It may be reached over a 
 ])rivate road half a mile long that leaves the Quatal Canyon road 4.7 
 miles east of its junction with U. 8. Highway 399. IMining of gyjisum 
 began iiere in 1941. 
 
 The Blue Diamond Corporation owns patented claims (103) that lie 
 between the IMonolitli property and Ballinger Canyon. Southeast of the 
 Monolith property and across (Quatal Canyon are the claims of W. 
 Mathews (107). The deposit extends still farther southeast into Corral 
 Canyon where the Heffron brothers have a gypsum claim. Development 
 only has been done on these properties. 
 
 The only published geologic report of the area known to the writer 
 is that of English '■' with its aci-ompanying map, scale 1 :12r),000. 
 
 English describes some 12,000 feet of coarse sediments of middle and 
 late ]\Iiocene age that occur in the area east of the Cuyama Valley and 
 west of the San Aiulreas fault zone. The sediments are at least in part 
 non-marine. The gypsum occurs at the base of the Quatal red clay, a 
 non-marine fades of the upper Miocene Santa ]\Iargarita formation. 
 T^nderlying the gypsum are the middle Miocene Caliente red beds.^'' 
 The Monolith property lies on the southwest flank of one of a series of 
 open, northwest-trending anticlines that lie cast of the Cuyama Valley. 
 
 '» English, W. A., Geology and oil prospects of Cuvama Valley, California : U. S. Geol. 
 
 Survey, Bull. 621, pp. 191-21.5. 1016. 
 ^ Dibblee, T. W., Personal communication. 
 
36 
 
 GYPSUM IN CALIFORNIA 
 
 
 
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 [Bull. 163 
 
 I 
 
 p»dd<j|s 
 
Parti] GEOLOOY 37 
 
 In the area mapped the gypsum bed is enclosed in 100 to 200 feet of 
 brown shale which in turn is enclosed in many liundred feet of coarse 
 sandstone. The Caliente red beds, wliich lie in the footwall, are composed 
 of a poorly consolidated sandstone tliat crops out on tlic steepest slopes 
 only. Tlie soil overlying- it is sandy and in many places contains igneous 
 pebbles and cobbles. One specimen of the sandstone is a poorly sorted 
 material in which the average grain size ranges from ,'„ to y\ inch, and 
 the ma.ximnm size is .{ inch. C! rains, which are snbangular, are mostly 
 (|uartz. Feldspar comprises less than 10 percent of the specimmi, and a 
 maximum of 5 percent is dark minerals and rock fragments. ]\Iost of the 
 (piartz grains are blue-gray in color, but .some are clear. 
 
 Tlic Quatal red clay that encloses the gypsum is a brown claylike 
 sliale that docs not form natural outcrops, even on the steepest slopes 
 in the area. Soil derived from it is a rich brown loam that supports grass. 
 The shale in places contains selenite crystals and is cut by satin spar 
 veinlets. 
 
 Shale was observed iiw })lac(' only in artificial openings. A six'cinicn 
 from the footwall in the Monolith quarry is a light brown material with 
 an irregular fracture. Selenite crystals up to an eighth of an inch in 
 length comprise ]ierhaps 5 percent of the specimen. No other minerals 
 are visible Avitli tiie hand lens. The footwall sliale is about 100 feet thick. 
 
 Shale overlying the gj'psum in the quarry is much like the footwall 
 shale. The color is lighter, and it has a conchoidal rather than an irregular 
 fracture. The hanging-wall shale here contains no gypsum, but elsewhere 
 soil derived from shale that overlies gypsum contains satin spar frag- 
 ments. Approximately 50 feet stratigraphically above the gypsum, beds 
 of fine-grained yellow sandstone occur in the shale and crop out in road 
 cuts. The total thickness of shale and fine-grained sandstone above the 
 gypsum is 75 to 100 feet; above that is coarse-grained sandstone similar 
 in all respects to the Caliente red beds. 
 
 The gypsum bed ranges from 10 to 30 feet in thickness, and in some 
 places it contains as much as 5 feet of interbedded shale. In artificial 
 openings the gypsum is massive and cut by joints jierpendicular to the 
 l)lane of the bedding, (iypsum crops out more conunonly than either 
 the sandstone or the shale, but the outcrops are of porous, weathered 
 material that gives but little indication of the character of the unweath- 
 ered gypsum below. Soil lying on gypsum is gypsite mixed with organic 
 matter resulting from the decay of coarse grass aiul bushes tiuit grow on it. 
 
 The gypsum itself is a brown-colored, compact aggregate of grains 
 about 0.05 inch in size in wliich there are indefinite segregations of 
 darker gypsum. Whatever causes the brown color does not, however, 
 affect the purity of the gy]>sum. Uiuler the microscojx' the gy])sum is 
 seen to be a mosaic of interlocking anhedral grains, many of which are 
 elongate but not oriented. Twinning is uncommon. (J rain size ranges 
 from 0.003 x 0.01 inch to 0.02 x 0.10 inch. Each crystal has uniform 
 extinction and well-defined boundaries. Cloudy brown calcite consisting 
 of anhedral grains less than 0.001 inch in diameter occur, commonly 
 along gj'psum crystal boundaries. There are also round bodies 0.01 inch 
 in diameter containing mixed gypsum and calcite. 
 
 A specimen of impure gypsum from the Blue Diamond area consists 
 of clear gypsum alternating with pai)er-thin layers clouded with brown, 
 opaque matter. The clear layers are composed of gypsum grains the size 
 
38 GYPSUM IN CALIFORNIA [Bull. 163 
 
 and shape of those described above except that almost all of them have 
 fibrous texture. The cloudy bands contain pypsum and auhedra of 
 dolomite or calcite 0.001 to 0.004 incli in size.' Finely divided opaque 
 dust occurs along the grain boundaries. 
 
 Within 5 feet of the base of tlie gypsum, nodules of gray to milky chert 
 are plentiful. Some are reniform ; others are lens-shaped. The nodules, 
 whicli may be up to 4 inches in diameter, are uniformly distributed 
 througli the lowest layers of the gypsum and average 5 to 10 feet apart. 
 
 A basalt flow, perhaps 20 feet thick, occurs 700 feet stratigraphically 
 below the top of the Caliente red beds in the Blue Diamond area. The 
 comparable stratigraphic position in the Monolith area falls on the face 
 of a steep scarp, and the flow was not located there. The flow is composed 
 of black-colored aphanitic rock, and it has reddened the underlying 
 sand somewhat. 
 
 The scarcity of good outcrops in the vicinity of the Monolith deposit 
 and the similarity of footwall and hanging wall rocks makes the inter- 
 pretation of the structure somewhat difficult. The surface northeast of 
 the branch canyon in which the quarries are is an approximate dip slope 
 that is abruptly cut off on the east by a steep scarp. Over much of the 
 dip slope gypsum crops out and dips uniformh* southwestward at angles 
 of from 30° to 45°. Toward the branch canyon the gypsum gradually 
 passes beneath the hanging wall shale and disappears southwest of it 
 under shale and sandstone. 
 
 At its upper edge the gypsum is abruptly cut off by an approximately 
 vertical fault the northeast side of which has dropped relative to the 
 southwest side. Northeast dips along the fault suggest that the gypsum 
 has been dragged down along the fault surface. Additional evidence of 
 the fault may be seen on the scarp where gypsum abuts against sandstone. 
 
 Some 600 feet northeast of the fault gypsum again appears on the 
 scarp in its normal secjuence. The outcrop of the gypsum bed is traceable 
 from here northwestward into the Blue Diamond area. Here also the 
 prevailing dip is southwest, although there are wide but perhaps local 
 departures from the regional trend. 
 
 Death Valley Region 
 China Ranch Deposit (31) (PI. 34) 
 
 A gypsum deposit on China Ranch southeast of Tecopa in sec. 26, 
 T. 20 N., R. 7 E., SBM, was worked in 1916 and 1917 by the Acme Cement 
 and Plaster Company. It is now owned by the Certain-teed Products 
 Corporation of Ardmore, Pennsylvania. The road to China Ranch, which 
 leaves the Tecopa-Noonday road about 3 miles east of Tecopa, passes 
 through the deposit. The deposit was opened wdth tunnels, and gypsum 
 was produced by open stoping at the rate of 1000 tons a month. 
 
 The gypsum occurs in a great thickness of tilted lake beds, probably 
 of Pliocene age, that are composed chiefly of brittle, light brown-colored 
 clay shale. Beds of pumice lapilli up to 15 feet thick occur interbedded 
 with the shale. The principal gypsum deposit is a 20-foot thickness of 
 gypsum beds ranging from 6 inches to 3 feet in thickness separated by 
 up to 3 inches of shale. On both the hanging wall and the footwall the 
 gypsum grades into shale by a rapid decrease in the number and thickness 
 of the gypsum beds. In addition thin beds of impure gypsum occur some 
 distance from the main bodv and selenite seams a quarter of an inch 
 
Part 1 ] GEOLOGY 39 
 
 thick cut tlie sliale. Tlu' jiyi).siiin is a coiiipact wliitc to iij^ht-gray a!Jrt?re<rate 
 of jrrains O.O'Jo to O.Oo iiu-h in size. In thin section the texture is seen 
 to be fibrous like tliat of the Fish Creek ^lountains gypsum. 
 
 Copper Canyon Deposit (32) (PI. 34) 
 
 An occurrence of gypsum was examined in Copper Canyon about 3 
 miles above its mouth in the northeastern part of T. 23 X., R. 2 E., 
 8BM. Comparatively thin jiypsuni beds occur in lake beds that lie on a 
 great thickness of conglomerate extending W(>stward to Death Valley. 
 The lake beds, which contain fossil footprints, have been assigned to the 
 lower Pliocene ( ?) Furnace Creek formation. Th(>y are composed of 
 chocolate brown-covered shale with a minor amount of coarse, pebbly 
 sandstone. Gypsiferous zones, although occurring throughout the lake 
 beds, are most numerous near the base. Most of the gypsum is in the 
 form of thin beds up to half-an-inch thick alternating with shale or 
 gypsiferous shale, but there are a few beds of i-omparatively pure gypsum 
 up to 5 feet thick. 
 
 Furnace Creek Deposit (33) (PI. 34) 
 
 There is an undeveloped gypsum deposit in Furnace creek on the 
 Twenty JIule Team scenic loop, on State Highway 190, 6 miles east of 
 Furnace Creek Inn. Gypsum beds which occur in the lower Pliocene ( '•) 
 Furnace Creek formation, crop out on the summit of a ridge between the 
 highway and the loop and extend along it for about a mile. A maximum 
 of 3 feet of pure gyp.sum occurs interbedded with shale ; greater thick- 
 nesses of gypsiferous shale and thin beds of gypsum alternate with shale. 
 Occurring near the gypsum are lava flows. Gy|isum in contact with the 
 lava is chalky, but there is no indication that this etl'ect was produced by 
 the lava. 
 
 Owl Hole Spring Deposit (86) 
 
 Near Owl Hole Spring in T. 18 N., R. 3E.. SBM. is an undeveloped 
 gypsum deposit that has some of the features of Avawatz ]\[ountains 
 deposits. It lies on a branch of the road to Leach Lake which early in 194S 
 had recently been graded and was marked with a sign. The branch turns 
 west from the Leach Lake Road 11.7 miles from the South Death Valley 
 road, and half a mile further on it passes through a narrow wash where 
 gypsum crops out on both sides. Gyjjsum and gypsiferous shale occur in 
 Pliocene ( .') lake beils that crop out along the wash for about a mile to 
 the east. These beds, which strike parallel to the wa.sh and dip north 
 beneath the wash gravel, are c(miposed of brown shale. The surface of the 
 shale is covered with a thin moldlikc efflorescence. 
 
 At the spot indicated above, a 2-foot bed of gypsum free of shale im- 
 purities crops out for 75 feet and continues across the wa.sh for a short 
 distance. Overlying the gypsum is a bed of salt-impregnated shale. Some 
 of the shale beds in the vicinity contain celestite nodules. 
 
 Cuddy Canyon Deposit, Kern County (37) 
 A gypsum deposit in Cuddy Canyon near Frazier Park has been ex- 
 amined by Gordon B. Oakeshott and James W. Vernon.-' The g\'psum 
 occurs in 'sec. 34, T. 9 X., R. 21 W., SB^M, about 2 miles west of Frazier 
 Park on the south side of the canyon. Although some gypsum has been 
 mined from the outcrop and an inclined shaft has been sunk, no records 
 
 -1 Supervising Mining Geologist and Junior Mining Geologist, respectively, California 
 Division of Mines. 
 
40 GYPSUM IN CALIFORNIA [Bull. 163 
 
 are available to indicate when the work was done or the use made of the 
 small amount of gypsum mined. 
 
 In this area the most prominent structural and topographic feature is 
 the San Andreas fault zone which trends almost due Avest following Cuddy 
 Canyon. North of the fault are bodies of er3-stalline limestone that occur 
 as roof pendants in Jurassic (?) granitic rocks, while south of it is a 
 series of volcanic and sedimentary rocks of Miocene ( ?) age containing 
 several gypsum-bearing lenses. The gypsum lenses are interbedded with 
 brown sandstone, conglomerate, basalt flows, basaltic agglomerate and 
 tuft' striking approximately N. 75" W. and clipping 20' to 85° south. The 
 largest of the gypsum lenses is 15 feet thick and can be traced southeast- 
 ward from the eanyon bed 700 feet up the hillside. The lenses consist of 
 laj'ers of light brown-colored gypsum as nnich as 8 inches thick separated 
 b}' the thinner layers of shale. 
 
 Mint Canyon Deposit, Los Angeles County (55) 
 
 Some development work has been done on a gypsum deposit in Mint 
 Canyon in the western part of sec. 29, T. 5 N., R.14 W., SBM. A gravel 
 road 6.2 miles north of Solamint turns east from U.S. Highway 6, and 
 0.3 mile from the highway a side road turns north to the deposit. The 
 deposit has been opened by a 150-yard eut along the gypsum outcrop, 
 but it was idle in November 1948. 
 
 A gypsiferous zone up to 15 feet thick that strikes N. 65° E. and dips 
 40° NW. occurs in tightly folded sedimentary and volcanic rocks of 
 the lower Miocene (?) Vasquez formation. The zone consists of beds 
 up to 6 inches thick of gray and brown-colored gypsum resembling that 
 of the Quatal Canyon deposit alternating with coarse, angular sandstone 
 cemented by gypsum. These rocks lie on a coarse, angular, greenish sand- 
 stone containing thin beds of purple-and green-colored shale. Twenty or 
 thirty feet below the gypsum occurs a black, somewhat vesicular lava. 
 Very coarse-grained arkosic sandstone containing a few 3-inch shale beds 
 overlies the gypsum. Granitic rocks are in fault contact with the sedi- 
 ments about 200 yards northwest of the deposit. 
 
 Mule Shoe Ranch Deposit, San Benito County (76) 
 The Mule Shoe Eanch deposit is 0.3 mile west of Bitterwater Road and 
 1.2 miles south of Bitterwater in sees. 17 and 18, T. 18 S., R. 9E., MDM. 
 (projected). It was last worked during 1945 and 1946 by the Monterey 
 Gypsum Company which produced high grade ground gypsum for agri- 
 cultural use.-- In December 1948 the operation was abandoned, and all 
 equipment had been removed. 
 
 Nearly flat-lying lenses of gypsum 3 to 6 feet thick and up to 300 yards 
 in diameter occur in beds of the Paso Robles (early Pleistocene) forma- 
 tion. The gypsum is enclosed in silt beds that in turn are enclosed in a 
 moderately hard, poorly sorted, cross-bedded sandstone containing 
 rounded pebbles of weathered siliceous shale up to half an inch in diam- 
 eter. Two to four feet of silt separate the gypsum from the overlying 
 standstone ; and the total overburden including a foot or two of soil ranges 
 from 3 to 10 feet in thickness. The underlying sandstone is exposed in the 
 bottom of a small canyon, a distance of about 25 feet stratigraphieally 
 below the gypsum. 
 
 a2 Averill, C. V., Mines and mineral resource.s of San Benitn rnunty, California : Califor- 
 nia Jour. Mines and Geology, vol. 43, p. 51, 1947. 
 

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DIVISION OF MINES 
 
 BULLETIN 163, PLATE 28 
 
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 ish shale. The distance from the floor of the canyon to the top of the picture 
 
 is about 20 feet. 
 
DIVISION OF MINKS 
 
 Bri.LETiN 163, PLATK 29 
 
 CYPSl'M AND ANHYDRITE 
 Fish Creek Mountains deposit, l^ight anhydrite, darl< gypsum. A boulder of 
 waste at the United States (iyjjsum Company (luarry. Anhydrite occurs abund- 
 antly in the nuarry about 120 feet vertically below the crest of the face. 
 
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DIVISION OP MINES 
 
 BULLETIN 163, PLATE 32 
 
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 PHOTOMICROGRAPH OF FIBROUS ANHYDRITE 
 
 Cut by satin spar veinlet, Fish Creek Mountains. Crossed nicols. 
 
Part 1 ] GEOLOGY 41 
 
 The gypsum itself is a compact, fine-grained, granular rock that is tan 
 in color. In the single specimen studied in thin section the texture re- 
 sembles that of the Quatal Canyon gypsum except that parts of the slice 
 contain subhedral to euhedral diamond-sliaped gypsum crystals. 
 
 Cuyama Valley Deposits, Santa Barbara and Ventura Counties 
 
 In tlie upper Cuyama Valley region there is a second gypsiferous zone 
 about 5 miles southwest of the Quatal Canyon deposit. The gypsum occurs 
 in the Caliente (middle Miocene) red beds; in this area the Santa Mar- 
 garita formation (late Miocene) which contains the gypsum at Quatal 
 Canyon, is non-gypsiferous.-^ Deposits along the zone for a distance of 
 about 7 miles were examined, and the zone probably extends farther in 
 both directions. In contrast to the Quatal Canyon deposit, however, the 
 zone consists largely of numerous thin beds of gypsum separated by 
 gypsiferous sediments. 
 
 Although development has been carried out at a number of places, 
 shipments have been small. In the summer of 1950 the Maricopa Gypsum 
 Company had made agreements to do assessment work on a number of 
 gypsum claims with options to lease them. The Cuyama Gypsum Company 
 held a license to produce agricultural gypsum in 1946. 
 
 The following is a list of properties where development work has been 
 done and from which a little gypsum may have been shipped. A deposit 
 belonging to L. Curyea in the SE] sec. 34, and SWj sec. 35, T. 9 N., 
 R. 25 W., SBM is on an eastern branch of Santa Barbara Canyon and 
 6.3 miles up the canyon from U.S. Highway 399 (100). The next property 
 to the east belongs to Ilarrv Black, Merl Black, and Gene Stutz. It is in 
 sec. 36, T. 9 N., R. 25 W. and sec. 1, T. 8 N., R. 24 W. SBM, in Wagon 
 Road Canyon 1.3 miles from its mouth (102). Between here and Cuyama 
 Wash is the Seeley property (101) in the SW-^ sec. 7 and NW^ sec. 18, 
 T. 8 N., R. 24 W. The River claim of Black et al (105) covers the gypsif- 
 erous zone where it crosses the Cuyama River. Development work has 
 been done in the northwest corner of sec. 17 and the northeast corner of 
 sec. 18, T. 8 N., R. 24 W. on the west bank of the river, and some gypsum 
 has been shipped from Frenchman's Point on the east bank in NE^ sec. 16 
 and NWi sec. 17, T. 8 N., R. 24 W. The easternmost property visited, 
 which is also part of the Black property, is a mile or so farther east on the 
 south side of Burges Canyon in NW^ sec. 15, T. 8 N., R. 24 W (104). At 
 all of these places the geologic occurrence of the gypsum is similar. 
 
 Those of the above deposits that are west of the Cuyama River are 
 in the area covered bj' English's map.-^ The gypsiferous zone occurs in 
 the middle Miocene Caliente red beds which English designated the Pato 
 member of the Vaqueros formation. These brightly colored red and green 
 nonmarine sandstones are especially noticeable in the beds overlying the 
 gypsum. They form a 2-mile strip bounded by faults that strike about 
 N. 60° W. through the entire area under consideration. Dips are pre- 
 dominantly southwest at angles of 25^" to 50°, but the fault block is itself 
 faulted, and there are northeast dips also. 
 
 Although the gypsiferous zone may be traced throughout the entire 
 area, it thickens at the places where development has been done to a 
 
 23 Dibblee, T. W., personal communication. 
 
 -* English, "W. A., Geologv and oil prospects of Cuyama Valley, California : U. S. Geol. 
 Survey Bull. 621, pp. 191-215, 1916. 
 
 8—58771 
 
42 
 
 GYPSUM IN CALIFORNIA 
 
 [Bull. 163 
 
Parti] GEOLOGY 43 
 
 luaxinium of 50 feet. These wider parts are composed of dark-brown 
 shale, fine-grained poorly consolidated quartzose sandstone, and com- 
 paratively thin beds of gypsum containing impurities of greenish-colored 
 shale. These rocks are thoroughly brecciated in many plaeos, and they 
 are commonly crowded with .satin spar veinlets up to an inch thick. The 
 highly gypsiferous portions of the outcrop are covered by blankets of 
 gypsite up to 5 feet thick. The section through the "Wagon Koad Canyon 
 deposit illustrates these features (fig. 8). 
 
 Development work has revealed beds of comparatively high grade 
 gypsum up to 10 feet thick. They are, however, extremely lenticular; 
 and commonly they disappear entirely within 100 feet along the strike. 
 Even smaller lenses of high quality alabaster are to be found. The 
 alabaster is used near Ventucopa for carving. Lenticular bodies of ala- 
 baster ranging in diameter from a few inches up to perhaps 10 feet occur 
 both within impure gypsum and in brecciated, gypsiferous shale. 
 
 A specimen of alabaster from Frenchman's Point was examined under 
 the microscope and found to consist almost entirely of gypsum in a 
 mosaic of slightly elongated interlocking cr^-stals that average 0.005 
 inch in length. There are a few large irregular anhedra of gypsum up to 
 0.02 inch in diameter that contain small gypsum crystals at a different 
 orientation from that of the surrounding material. 
 
 Avawatz Mountains Deposits, San Bernardino County (79) 
 
 Gypsum, together witli salt and celestite, occurs in a belt of strongly 
 folded and faulted Tertiary beds that are exposed in the northern foot- 
 hills of the Avawatz Mountains. These beds crop out in a belt about 9 miles 
 long and a mile wide that extends from sec. 8, T. 17 N., R. 6E., near Sheep 
 Creek northwestward to sec. 24, T. 38 N., R. 4 E., 8BI\I. The deposits are 
 included in claims of the Avawatz Salt and Gypsum Company that were 
 patented about 1911. There has been no production, and no work has been 
 done on the gypsum deposits in recent years. Exploration of portions of 
 the salt deposit carried out in 1941 and 1942 had no direct bearing on the 
 gypsum. The Western Atlas Corporation held a lease on the property 
 and developed talc bodies associated with the basement rocks. The 
 property is remote from paved highways, although some of the old access 
 roads have been regraded. Although the road from Barstow through 
 Camp Irwin is passable, the best approach is from the South Death 
 Valley road. 
 
 The only detailed and comprehensive geologic report on the Avawatz 
 saline deposits is the unpublished report of Lewis and Johnson. ^"^ A 
 report written by XL C. Lee and L. F. Boyer, in 1942, also unpublished, 
 is confined to a small portion of the salt deposit where gypsum does not 
 occur. Gale ^^ has summarized and evaluated the earlier work after re- 
 viewing the area in the field with L. F. Noble. Gale's report, primarily 
 on the salt resources, contains a geologic map of the central third of the 
 Avawatz Salt and Gypsum Company propert3^ 
 
 Structurally the region is so complex that no uniformity of opinion 
 exists among those who have studied it in detail. The salines occur in lake 
 beds of late Miocene or early Pliocene age and were formed by evapora- 
 tion of the water of a closed basin or basins. The Tertiary beds are 
 
 =5 Lewis, J. O., and Johnson, H. R., Unpublished report prepared for the Avawatz Salt 
 
 and Gypsum Company, July 31, 1911. 
 " Gale, H. S., Avawatz salt, grypsum, celeslte and talc deposits, San Bernardino County, 
 
 California, 37 pp., unpublished manuscript, December 1947. 
 
44 GYPSUM IN CALIFORNIA [Bull. 163 
 
 involved in the South Death Valley fault system, a series of faults that 
 may be traced for at least 30 miles northwestward along the south side 
 of Death Valley. The merging of this fault system with the Garlock 
 fault near Sheep Creek in the eastern end of the property is the apparent 
 reason for the structural complexity of the area. 
 
 In the opinion of those who have worked in the area recently, the 
 granitic and metamorphic rocks that form the main mass of the Avawatz 
 Mountains have been thrust northeastward over the Tertiai-y rocks.^^ 
 
 The following interpretation of the stratigraphy is by Lewis and 
 Johnson with slight modifications by Gale. One prominent formation is 
 a breccia, probably of Tertiary age, composed of rocks similar to those 
 of the core of the Avawatz Mountains where gneiss, marble, and quartzite 
 have been intruded by granite and gabbro. In the area under considera- 
 tion the breccia occurs in two steeply dipping slices, one facing Death 
 Valley and one farther south, separating two belts of complexly folded 
 and faulted gj^psum and salt-bearing Tertiary lake beds. The two belts 
 of Tertiary rocks are close together at the east end of the property and 
 diverge westward at a slight angle. 
 
 The gypsum- and salt-bearing beds are divisible into four parts. The 
 older Tertiary beds, which contain neither salt nor gypsum, are made 
 up of a lower section of maroon-colored or deep red-colored shale and 
 an upper section of fine-grained argillaceous j-ellow-colored sand. Their 
 thickness is 267 feet at Cave Spring Wash. 
 
 The older Tertiary beds grade upward into the gypsum-bearing beds, 
 which range from 150 to 400 feet in thickness. The base is marked by 
 the first appearance of gypsum in quantity and the top hy the last ap- 
 pearance of gypsum. Gypsum occurs as relatively thin beds of fine- 
 grained rock gypsum alternating with greenish gypsiferous clay and 
 forms from a small fraction up to two-thirds of the total thickness. Some 
 of the gj^Dsum is heavily stained with manganese oxides, but in general 
 it is free from salt. Particularly in the western part of the property, 
 celestite is found near the base of the gypsum-bearing beds. The celestite 
 occurs as reef -forming beds of hard, dark-weathering rock up to 3 feet 
 thick that may be traced for as much as 1.000 feet. Along the strike, 
 they thin out and are represented by nodules of celestite in gypsum. 
 
 The salt-bearing beds overlie the gypsum and consist of yellowish and 
 reddish salty clay and sand that contain rock salt in the central part. 
 The thickness is difficult to determine because of the lack of structures 
 in the salt. Although the salt is in general concealed by a layer of residual 
 impurities, exploration in the Boston- Valley salt claims has disclosed 
 275 feet of massive salt, averaging more than 92.0 percent NaCl. The 
 salt-bearing beds grade upward into the post-salt beds, 800 feet of 
 gravel and sand containing a minor proportion of gj^psiferous and 
 saline beds. 
 
 Overljang the post-salt beds with marked angular unconformity are 
 beds of boulder conglomerate that are horizontal or broadly folded. Noble 
 has correlated them with the Funeral fanglomerate of probable late 
 Pleistocene age. Still younger, but older than the Recent terrace gravels 
 and alluvium, is the older alluvium, remnants of alluvial fans that have 
 been dissected by later stream channels. 
 
 "' Hewitt, P. Li., Personal communication. 
 
Parti] GEOLOGY 45 
 
 The detailed structure of the two gypsum- and salt-bearing belts has 
 not been solved. In part, at least, this is because of the lack of detailed 
 study, for only in one limited area has a complete program of explora- 
 tion been carried out. In part, tlie massive character of the salt obscures 
 structures in it. Interpretations of the structure by different geologists 
 are widely divergent. The relative ages of the sediments have not been 
 definitely determined, and it has even been questioned that the normal 
 order of precipitation of gypsum followed by salt took place here. 
 
 The folknving five areas are illustrative of the general nature of the 
 gypsum deposits (pi. 36). 
 
 The West End. Some low hills at the west end of the Avawatz Salt 
 and Gypsum Company property and in the broad fan slopes northwest 
 of Denning Spring are known as the West End. The old road from 
 Denning Spring to Confidence Mill lies about half a mile east of these 
 hills, and early in 1948, it was possible to drive north on it to a point 
 east of the hills. Because of the relatively low relief and small amount 
 of overburden, the West End has been considered to be the most favor- 
 able place to mine gypsum. 
 
 In these hills the g}'psum-bearing beds are involved in two or more 
 domal anticlines revealed under the terrace and wash gravels, and arc 
 covered with little, if any overburden. Although they dip steeply south- 
 west, the beds are less contorted here than elsewhere on the property. 
 The accompanying section shows a maximum thickness of 150 feet con- 
 sisting of gypsum beds up to a foot thick separated by thin layers of 
 clay. This relatively pure gypsum grades both upward and downward 
 into interbedded gypsum, clay, and sand, with a decreasing proportion 
 of gypsum. Certain beds are heavily stained wdth manganese and iron 
 oxides. 
 
 Celestite is more abundant in the West End than elsewhere in tiie 
 property. It occurs both as solid beds and as layers of nodules within the 
 gj'psum. 
 
 Big Gypsum (Kellcy) Hill. Big CTypsura (Kelley) Hill, a conspicuous 
 outcrop of gypsum on the northwest side of Denning Spring AVash, is 
 the northwest extension of the same belt of lake beds that occurs in Salt 
 Basin. A rough but passable road that turns south from the South Death 
 Valley road and follows the wash, passes close to the southwest end of 
 the hill. Tlie gypsum is 1.5 miles from the South Death Valley road. 
 
 The structure has not been determined definitely. Although as seen 
 from a distance the gypsum-bearing beds apparently lie on the brecciated 
 basement rocks with normal depositional contact, a complicated system 
 of faults has been postulated to explain the relations observed. Depending 
 on the interpretation of the structure. Big Gypsum Hill may or may not 
 contain a large tonnage of gypsum. 
 
 Salt Basin. Salt Basin, a valley trough formed by the dissolving of 
 salt, is flanked on the north by a considerable thickness of the gypsum- 
 bearing beds. The gypsum has received more study in this area than in 
 any other part of the property. Salt Basin is best reached from the unim- 
 proved road in Denning Springs Wash, from which, 1.3 miles south of 
 the South Death Valley Road, a branch turns southeastward and crosses 
 Cave Spring Wash to the deposit. 
 
46 GYPSUM IN CALIFORNIA [BuU. 163 
 
 The accompanying section extends between the two ridges of brecciated 
 basement rocks and crosses the northern belt of gypsum- and salt-bearing 
 lake beds. The structurally weak gypsum-bearing beds, which have been 
 intricately contorted and tightly folded, are exposed in gulches that 
 flow northeast into Salt Basin. In addition, a prospect tunnel lias cut 
 200 to 300 feet of the beds. 
 
 On the south, breccia is in fault contact with relatively undisturbed 
 mudstone. This slightly consolidated, but well-bedded material is gray to 
 red in color and contains conglomerate lenses and a minor proportion of 
 thin gypsiferous layers. Possibly in fault contact with the non-gypsifer- 
 ous beds are interbedded gypsum and gypsiferous clay beds that are 
 intensely crumpled and stand nearly vertically. Although some gypsum 
 beds are up to 10 feet thick, the dump at the prospect tunnel suggests 
 that the section as a whole contains a large proportion of clay. 
 
 NorthAvard the gypsum-bearing beds grade into gray to reddish mud- 
 stone that becomes salty. Salt is believed to lie beneath the floor of Salt 
 Basin, and around the sides salt forms outcrops covered with red-brown 
 clay that is in marked contrast with the tan outcrops of the gypsum- 
 bearing beds. North of Salt Basin the salt is followed by steeply dipping 
 salty mudstone that is in fault contact Avith brecciated basement rocks. 
 
 Jmnho Deposit. The Jumbo deposit is in the north belt of lake beds, 
 about 2 miles southeast of Salt Basin. It may- be reached from the South 
 Death Valley road on an unimproved track that begins 5.6 miles from the 
 State Highway 127 and follows an unnamed wash. Salt and gypsum occur 
 on the east branch of this wash 4.0 miles from the South Death Valley 
 road. 
 
 The lake beds, as shoAAm in the accompanying section, are in fault con- 
 tact on the south with brecciated marble and granite. Northward lie sev- 
 eral hundred feet of crumpled gypsiferous mudstone and sandstone and 
 then 20 to 30 feet of gypsum comparatively free from clay. In fault con- 
 tact with the gypsum beds is a massive body of salt, the outcrop of which 
 is 150 feet wide. North of the salt and in fault contact with it are gypsum 
 and clay beds that become less gypsiferous northward before disappear- 
 ing beneath terrace and wash gravels. 
 
 Sheep Creek Deposit. The Sheep Creek gypsum deposit is at the east- 
 ern end of the Avawatz Salt and Gypsum Company property and close 
 to the intersection of the Oarlock and South Death Valley fault systems. 
 The Sheep Creek talc deposit, which is associated with the basement rocks, 
 lies about half a mile to the north. A road, marked by a sign in 1948, goes 
 from the South Death Valley road for about 5 miles to a cabin near Sheep 
 Creek Spring. The gypsum lies about a quarter of a mile farther up 
 the first canyon tliat bears to the west. 
 
 The gypsum-hearing beds occur in a belt about 200 yards wide that is 
 bounded by steeply dipping faults. Brecciated granitic and metamorphic 
 rocks lie both to the north and to the south, and about half a mile to the 
 east the belt of lake beds pinches out. The lake beds are severely contorted 
 and are either vertical or dip steeply northwest. Oypsum occurs in them 
 as beds up to 6 inches thick that are separated by thin layers of powdery 
 greenish clay. 
 
Part 1 ] GEOLOGY 47 
 
 QUATERNARY LAKE (PLAYA) DEPOSITS 
 
 Some of the playa lakes found in ck-sert rej^ions contain enough gyp- 
 sum to be commercial sources. Playas are those undrained desert basins 
 that are almost entirely filled with mud. Although they may be covered 
 with a few inches of water after heavy rains, normaily the water level is 
 some distance below the surface ; and they present an expanse of dried 
 mud covered with an eHlorescence of evaporated salts. A small proportion 
 of the playas contain crystal bodies of mixed salts that form a porous 
 mass filled with the mother liquor from which the salts crystallized. The 
 crystal body occupies but a small part of the playa. The gypsum in playas 
 is usually in the form of a mesh of selenite crystals from a quarter of an 
 inch up to an inch long or more. 
 
 Bristol Lake, San Bernardino County 
 
 The most important source of playa gypsum in California is P^ristol 
 Lake, San Bernardino County, near Amboy. From 1906 to 1924 gypsum 
 obtained from the lake about' 2 miles southeast of Amboy in sees. 3 and 
 10, T. 5 X., K. 12 E., SBM. (81), supplied the largest plaster mills in 
 California at the time. The first mill, built by the Pacific Cement Plaster 
 Company, w^as at Amboy; but about 1916 a new mill was built on the 
 lake clo.se to the deposit. This property now belongs to the TTnitod States 
 Gypsum Company, which also owns land in sees. 19 and 30, T. 5 N.. 
 R. 12 E., SP.M. south of Amboy and on the west side of the lake. In 1935 
 the Bolo Gypsum Company held property on the east side of the lake (80) 
 but there is no record of production. 
 
 Bristol Lake, which lies in a trough, is filled with brine-saturated, fine 
 sediments covered by a hard, salt-crusted surface. In the central part of 
 the lake extensive beds composed primarily of common salt lie within 
 4 to 8 feet of the surface, while the underlying mud is saturated with con- 
 centrated brine containing sodium chloride and calcium chloride. One or 
 more deeper salt beds are believed to exist but have not been explored. 
 Selenite crystals and celestite nodules are found in the mud near the 
 lake margin. 
 
 Gypsum has been found at or close to the surface and within a mile of 
 the shore all around the lake, but it is most abundant on the west and 
 north sides. Salt beds do not occur in these marginal areas. Although the 
 character of the gypsum varies, in most places a mush of selenite crystals 
 mixed with salty mud lies beneath a few inches of silt covered with a 
 salty crust. Crystals on the west side of the lake are ■^,- to ^-inch in size 
 and comprise perhaps two-thirds of the mass, while those near the site 
 of the calcining plant are flat plates up to an inch long, half an inch wide, 
 and one-eighth-inch thick. ITess ^s states that in the areas being worked 
 in 1909, gypsum extended from within a foot of the surface to an unknown 
 distance below the level of the water, which rose to within 8 feet of the 
 surface. Of the excavations on the west side of the lake, which were ex- 
 amined in 1948, few are deeper than 4 feet ; and in many of them the gyp- 
 sum content is greatest about 3 feet below the surface. 
 
 In the 1906-1924 operation, the gypsum from Bristol Lake required 
 special treatment to remove the salt and silt before it was processed 
 further. 
 
 28 Hess, F. L., California, in Stone, R. W.. and others, Gypsum deposits of the United 
 States : U. S. Geol. Survey, Bull. 697, p. 82, 1920. 
 
48 GYPSUM IN CALIFORNIA [Bull. 163 
 
 Danby Lake (85), San Bernardino County 
 
 Danby Lake, San Bernardino County, contains deposits of selenite that 
 resemble those of Bristol Lake, but there has been no production.^'' Danby 
 Lake lies roughly 35 miles southeast of Bristol Lake, and the two occupy 
 the same structural trough. The Parker branch of the Santa Fe Railroad 
 runs along the northeast shore of the lake. B3' road Danby Lake is best 
 approached from the southeast. The road from Freda Station on the Des- 
 ert Center-Yidal highway to Saltmarsli station on Danby Lake was pas- 
 sable in 1951. 
 
 Danby Lake, like Bristol Lake, contains a bed of salt ranging from 2 
 to 10 feet thick and covered by from 3 to 15 feet of overburden; but the 
 brine, with which it is saturated, contains no appreciable quantity of cal- 
 cium chloride. The salt lies in the central part of the lake, including the 
 area from sec. 21, T. 2 N., R. 17 E., SBM. to sec. 23, T. 1 N., R. 18 E., SBM. 
 Northeast of the central area that contains the salt, the marginal silt 
 contains abundant clusters of selenite crystals an inch or more in size. 
 They were observed about 2 miles S. 21° E. of Saltmarsh station, where 
 selenite crystals comprise up to a third of the lake beds exposed at the 
 surface. It is possible that the selenite may extend along much of the 
 northeast shore of the lake, but this has not been ascertained. 
 
 Where selenite is abundant, numerous knobs as much as 15 yards in 
 diameter project 5 or 10 feet above the lake surface. They are composed 
 of silt mixed with gypsum crystals approximately 0.01 inch in size and 
 possess a crude layering that is nearly vertical, mushrooming upward 
 and outward. Probably the knobs were formed by the evaporation of 
 upward-moving water that contained calcium sulfate. 
 
 RECENT DEPOSITS (GYPSITE) 
 
 Gypsite is an unconsolidated earthy mixture of very finely divided 
 gypsum and clay or silt. Calcium carbonate is usually present. Samples 
 may contain 80 percent or more gypsum, but because of the irregularity 
 of the deposits little of the gj'psite on the market is guaranteed to contain 
 more than 70 percent gypsum. Much of the gypsite used for agricultural 
 purposes contains from 50 to 60 percent gypsum, and some material with 
 a gypsum content of only 30 percent has been sold. The deposits usually 
 are at or within a few inches of the surface. Deposits as thin as 6 inches 
 liave been worked, and few exceed 6 feet in thickness. 
 
 Gypsite forms only in regions of little rain and high evaporation. 
 Capillary action draws calcium sulfate-bearing ground water toward 
 the surface where very small crystals of gypsum form. Gypsite deposits 
 are especially numerous and best known in the southwestern part of the 
 San Joaquin Valley. Here their proximity to the San Joaquin Valley 
 farms has made their mining profitable. Gypsite occurs also at many 
 jilaces outside the San Joaquin Valley, and some of the deposits are 
 being worked or have been in the past. Deposits at Koehn Lake, Kern 
 County, and a number of places in the southern Coast Ranges are 
 being worked today. Gypsite has also been mined at Palmdale, Los 
 Angeles County; Corona, Riverside County; and in Carrizo Plain, San 
 Luis Obispo County. Gypsite is commonly associated with the large 
 
 2" Noble, L.. P., Nitrate deposits in southeastern California with notes on deposits in 
 southeastern Arizona and southwestern New Mexico: U. S. Geol. Survey Bull. 820, 
 pp.57, 58, 1931. 
 
Parti] GEOLOGY 49 
 
 deposits of rock gypsum that occur in the desert but are too remote to 
 be of economic interest. 
 
 Tliree types of ^'ypsite deposit have been recognized ; those that form 
 caps on the upturned edges of gypsiferous beds, those that occur along the 
 margins of certain periodic lakes, and those that have formed in the 
 beds of dry washes. Deposits that have formed on the upturned edges 
 of gypsiferous beds are probably the most numerous. The gypsum in 
 the source beds may be in the form of selenite crystals and cleavage 
 plates, as part of the cement of sandstones, as a network of satin spar 
 veins, or as thin layers of gypsum interbedded with shale. The overlying 
 gypsite bodies closely parallel the present surface except that the thin 
 overburden of soil is likely to be thinner high on hillsides than it is 
 toward the base. Usually the gypsite becomes less pure downward and 
 grades into the underlying gypsiferous source material. On slopes some 
 migration of gypsite takes place because locally gypsite may lie on non- 
 gypsiferous rock. Individual bodies vary in size from patches up to 
 deposits covering several acres. The average maximum thickness is 3 or 4 
 feet, but thicknesses of as much as 8 feet occur in a limited area. The 
 'jfypsite is tan to cream in color and is usually soft. It is composed of 
 unconsolidated crystals of gypsum 0.002 inch or less in length, mixed 
 with quartz grains. 
 
 Relatively large gypsite bodies occur along the margins of periodic 
 lakes. Efflorescent deposits have formed along the shore line from calcium 
 sulfate dissolved in the damp underlying soil even though the lake water 
 itself may never have been saturated with gypsum.^*' Gypsite bodies so 
 formed are flat irregular lenses that lie with a sharp contact on lake beds. 
 Sometimes the gypsite crops out, but usually it is covered with up to 3 
 feet of sandy soil. Solution cavities and interbedded layers and lenses 
 of gravel or unconsolidated sand are a characteristic feature. Specimens 
 of gypsite from these deposits resembles that which forms on outcrops 
 except that the gypsum crystals of the lake margin type are about 
 0.004 inch long or a little larger. 
 
 The third type is represented by gypsite deposits near McKittrick 
 that have formed in the beds of dry washes. They are long, narrow, 
 crooked bodies covered by up to 5 feet of slightly consolidated sand and 
 gravel. Gypsite occurs on the surrounding hills, and the gypsite in the 
 channels may have been washed in from the hills. The channel gypsite 
 may also have originated from gypsiferous ground water that accumu- 
 lated in the channels. 
 
 Fresno County Deposits 
 
 Little Panoche Valley Deposit^* (9) 
 
 Tlio Little Panoche Placer deposit is operated by A. D. Sousa of the 
 Agricultural Minerals and Fertilizer Company. Los Banos, and was 
 opened by him in 1946. The deposit is located in SEl NW^ and NEj SW-j 
 sec. 1. T^ 14 S., R. 10 E. MDM. In 1949 it could be reached over an 
 unimproved road 1.5 miles long that leaves the Tiittle Panoche Valley 
 road 5 miles south of Mercy Hot Springs. 
 
 The deposit consists of a comparatively small patch of gypsite perhaps 
 500 feet in diameter and averaging 2 to 3 feet thick that lies on a north- 
 
 »Hess, F. L... California, in Stone, R. W. and others, Gypsum deposits of the United 
 
 States: U. S. Geol. Survey Bull. 697, pp. 71-T3, 1920. 
 ^ See also Merced County. 
 
50 GYPSUM IN CALIFORNIA [Bull. 163 
 
 west-trending spur of the Panoche Hills. Bedrock in the vinicity of the 
 deposit is largely covered by soil, and the base of the gypsite has not yet 
 been exposed. A steeply dipping bed of coarsely crystalline limestone 
 crops out discontinuously along one edge of the deposit and may be traced 
 several hundred yards. Elsewhere within the gypsite are outcrops of 
 greenish, arkosic sandstone. 
 
 Gypsite from this deposit is guaranteed to contain 70 percent gypsum. 
 Mining is done with a scraper operated by a double drum hoist. 
 
 Panoche Hills Deposits 
 
 The Panoche hills deposits are on the east flank of the Panoche hills 
 at an elevation of about 100 feet above the floor of the San Joaquin 
 Valley. They are 20 to 25 miles south of Dos Palos. Gypsite was first 
 mined hero by Paul Schuck prior to 1913. The Dos Palos Gypsum Com- 
 pany (Divens and Conrowe) was active from 1933 to 1941, while Green 
 and Collins worked a deposit adjoining the Dos Palos Gypsum Company 
 operation on the south from 1934 to 1939. In 1947 the Super Gypsum 
 Company began working approximately the same ground as Green and 
 Collins, and in 1948 E. P. Jones reopened the deposit adjoining on the 
 north that had been worked earlier b}^ Divens and Conrowe. 
 
 The Valley View mine (17) of K. P. Jones is in sec. 19, T. 14 S., R. 12 E., 
 MDM. An unimproved road marked in 1949 by a sign leaves the Dos Palos 
 Road 19.3 miles south of the railroad crossing at South Dos Palos. The 
 deposit is 3.7 miles from the road junction. 
 
 The bed rock here, a member of the Domengine (Eocene) formation, 
 is a soft sandstone, containing Turritellas, that has more indurated beds 
 about 20 feet apart. The weathered rock is purplish-red in color, and 
 much of it is cut by closely spaced satin spar veinlets. At least in places 
 the unweathered rock contains little or no gypsum. The beds dip at about 
 30° toward the valley and strike at a slight angle to the northeast- 
 trending spurs that project toward the valley from the main mass of 
 the Panoche Hills. Gypsite occurs on the tops of these ridges and extends 
 down the flanks. It extends farther down the northwest flanks than 
 the southeast flanks, perhaps because the surface is more nearly normal 
 to the dip of the beds on the northwest flanks. In the intervening gullies 
 gypsite is either lacking or thin and deeply buried. A cut in a gully 
 bottom 10 to 15 deep that was excavated for a loading chute penetrated 
 no gypsite. At another place a few inches of gypsite were found beneath 
 20 feet of alluvium. 
 
 Individual gj'psite bodies are small and irregular and are covered in 
 most places by a foot of soil. The gypsite grades downward into the 
 underlying bedrock. In places sand derived from the sandstone lies 
 beneath the gypsite. INIany of the bodies are full of residual stones and 
 a shaking screen with f-inch openings has been installed to remove as 
 much as possible of the non-gypsiferous material. Gypsite sold from the 
 Valley View mine is guaranteed to contain 50 percent gypsum. 
 
 Tumey Gulch Deposits 
 
 The gypsite deposits of Tumey Gulch occur on northeast-trending 
 spurs of a ridge that lies between the San Joaquin Valley and the mouth 
 of the gulch. The Paoli Gypsum Company produced some gypsite here 
 before 1900 from the northeast corner of sec. 1, T. 16 S., R. 12 E., MDM, 
 and a study of the deposit was made by Professor E. "W. Hilgard of the 
 
Parti] GEOLOGY 51 
 
 University of California soon after gypsite was discovered there.^- A. P. 
 Shepard's Paoli mine produced a substantial tonnage from 1930 to 1939, 
 thus being among the first to enjoy the modern boom in agricultural 
 gypsum. The Paoli mine was in sees. 1 and 2, T. 16 S., R. 12 E., MDM, 
 partly on Shepard's own land and partly on land belonging to II. II. 
 Welsh. Gypsite was recently produced by two enterprises, J. K. Griffin, 
 trustee of the II. II. Welsh estate, and the Bahr mine. 
 
 The Bahr mine (6) is on land leased from the Welsh estate in sec. 1, 
 T. 16 S., R. 12 E., MDM, and it adjoins the Griffin deposit on the east. 
 Gypsite had been produced here in 1947, but the deposit was idle in 
 December 1948. Gypsite occurs on the flanks of spurs trending toward 
 the San Joa(iuin Valley and at a considerable distance from the main 
 ridge bordering Tuniey Gulch. Maximum thickness is 3 feet, and much 
 of it contains impurities of sand and gravel. 
 
 The Tumey Gulch deposit (16) of J. K. Griffin is in see. 1, T. 16 S., 
 R. 12 E., MDM, at the mouth of Tumey Gulch. It is west of the Bahr 
 mine and at a higher elevation. Bedrock is a poorly consolidated sand- 
 stone of the Vaquerus (]\Iiocene) formation that lies on a more indurated 
 sandstone containing brown fossiliferous beds. The bedrock is covered 
 in most places with 2 to 3 feet of gravel composed of sandstone and a 
 minor amount of quartz and chert. Small scattered gypsite bodies occur 
 almost invariably on the slopes of the spurs that trend northward from 
 the ridge bordering Tumey Gulch. The average maximum thickness of 
 gypsite is 4 feet, but thicknesses of 8 feet are known over a limited area. 
 Although there are a few outcrops, gypsite is in most places covered 
 with sandy soil that is in sharp contact with the gypsite. At the base the 
 gypsite grades into sand and gravel that commonly contains crystals 
 and cleavage fragments of selenite ^ to ^ inch in size. A carryall scraper 
 was used for both stripping and mining the gypsite. A screen and 
 hamnier mill have been installed to produce a ground product. The 
 deposit has not been worked since 1949. 
 
 Griffin also mined gypsite from sec. 6, T. 16 S., R. 13 E., MDM, and 
 gypsite extends southeastward into sec. 3, 4, and 5 along Monocline 
 Ridge. In the Tumey Gulch area the mineral rights of parts of the Welsh 
 propertv now belong to S. C. Lillis. These include parts of sec. 36, T. 15 S., 
 R. 12 e!^ and see. 2, T. 16 S., R. 12 E., MDM. 
 
 Kern County Deposits 
 Kern Lake Deposits 
 
 Gypsite on the south margin of Kern Lake, which has been drained, was 
 described by IIcss-'-* in 1910. Iless' theory of the origin of the gypsite 
 found on the margins of some periodic lakes was based in part on a study 
 of these deposits. No production was made, however, until the Pacific. 
 Gypsum Company in 1946 and the Crystal Gypsum Company in 1947 
 commenced operations. 
 
 The Crystal Gypsum Company's deposits (36) are in sees. 27, 34, and 
 35, T. 32 S.. R. 27 E., near the .south margin of Kern Lake. The property, 
 which adjoins the Pacific Gypsum Comnany's holdings on the south and 
 west, may be reached from the Old Maricopa Road at a point 5.2 miles 
 west of U. S. Highway 99 where a road 1.1 miles long leads to the deposit. 
 
 '2 Mines and mining products of California : California State Min. Bur. Rept. 12, pp. 323, 
 
 324, 1894. 
 ^ Hess, P. L,., California, in Stone, R. "W., and others, Gypsum deposits of the United 
 
 States : U. S. Geol. Survey Bull. 697, pp. 71-73, 1920. 
 
52 GYPSUM IN CALIFORNIA [Bull. 163 
 
 Numerous shallow pits and test cuts have exposed lake beds and small 
 unmined remnants of gypsite. The pits range in size from 10 yards in 
 diameter and 1 foot in depth to 100 yards in diameter and 3 feet in depth. 
 Apparently the gypsite was in the form of comparatively small, scattered 
 lenses. In December 1948 many of the pits were flooded, and the property 
 was idle. 
 
 The Pacific Gypsum Company is operating a gypsite deposit (46) in 
 sec. 26, T. 32 S., R. 27 E. on the south margin of Kern Lake and east 
 of the Crystal Gypsum Company's property. The deposit may be reached 
 over a 1.3 mile access road that leaves the Old Maricopa Road 4.5 miles 
 west of U. S. Highway 90. In December 1948 the route was well marked 
 with signs. Numerous lenticular bodies of gypsite 1 to 3 feet thick lie 
 within 3 feet of the surface. The upper part of the gypsite is clean and 
 soft ; downward it becomes harder and contains streaks of included mud. 
 A sliarp but irregular contact separates the gypsite from the underlying 
 brown clay. The gypsite lenses thin abruptly toward the edges and contain 
 an increasing proportion of mud. In many cases the limit of gypsite of 
 commercial grade is an approximated vertical plane. Solution cavities 
 and sinks up to 3 feet in diameter that occur in the gypsite are a prominent 
 feature of this deposit. Gypsite from this deposit is guaranteed to contain 
 60 percent gypsum. Two carryall scrapers are used for mining and strip- 
 ping. 
 
 Koehn Lake Deposit (41) 
 
 A gypsite deposit of the lake-margin tvpe exists in the southwest part 
 of Koehn Dry Lake in sec. 28, T. 30 S., R. 38 E., MDM. Hess visited the 
 area and described the occurrence soon after its discovery in 1909.^^ For 
 a few 3'ears following the discovery this gypsite supplied a small calcining 
 plant on the lake, but most of the production has been for agricultural 
 purposes. G.W. Abel leased the deposit in 1926 and operated a grinding 
 plant for a time. Later, C. A. Koehn produced gypsite on a small scale 
 until his death ; and Mrs. Koehn, now Mrs. Daly, has continued the 
 enterprise. 
 
 The pit in operation during 1948 could be reached on good roads by 
 driving IJ miles south from Cantil and then 4 miles east. From here an 
 unimproved track leads to the pit, a mile to the north. One or two feet 
 of grass-covered soil lies on the gypsite which has been exposed in a pit 
 100 yards in diameter and up to 5 feet deep. The base of the deposit has 
 not been exposed in the present workings. The gypsite, a white, fine- 
 grained material having the consistency of packed snow, is cut by thin 
 layers of clay and limonite that are parallel to the surface and a foot or 
 two apart. Gypsite currently produced is guaranteed to contain 60 per- 
 cent gypsum. The gypsite is mined and loaded into trucks with a Haiss 
 creeper-model loader. 
 
 Lost Hills Deposits 
 
 Although Hess reported the occurrence of gypsite near Lost Hills in 
 1910.-^^ mining was not undertaken until 1930. In 1934 H. M. Hollo- 
 way Incorporated, now the largest producer of gypsite in California, 
 began production near Lost Hills. In addition to the Holloway Company 
 
 " Hess, P. Ti. Gypsum deposit near Cane Springs, Kern County, California : U. S. Geol. 
 
 Survey Bull. 430, pp. 417, 418, 1909. 
 «sHess, F. L., California, in Stone, R. W., and others, Gypsum deposits of the United 
 
 States : U. S. Geol. Survey Bull. 697, pp. 65-67, 1920. 
 
Part ] ] ' nEOTiOoy 53 
 
 other gypsite producers at Lost Hills have been Handel and Son from 
 1941 to 1944, the Star Gypsnm Company in 1943 and 1944, and the Theta 
 rjypsiim Company from 1941 to 1943. 
 
 The Ilolloway deposits^*' (43) wliich lie along the western side of the 
 Lost Hills, are in sees. 3, 10, 11, 14, 15, 23, 24, 25, and 20, T. 2G S.. 
 R. 20 E., MUM. They may be reaehed from a road paralleling the Lost 
 Hills that leaves U.S. Highway 466 about 3 miles west of Lost Hills. Gyp- 
 site bodies are scattered along tlic Lost Hills for a distance of about 4 
 miles. 
 
 The Lost Hills deposits possess some of the features of the lake margin 
 type. Flat-lying lenses of gypsite, some as much as 20 feet thick, occur 
 in slightly consolidated silty sand that contains lenses of gravel. Usually 
 the gypsite lies within 3 feet of the surface, but some bodies are covered 
 by 10 feet of alluvium. Many of the bodies are elongate and resemble in 
 shape the channel deposits of McKittriek. 
 
 Gypsite near the centers of lenses is a nearly white, sugary material 
 made up of interlocking plates of gypsum 0.005 inch in diameter. Calcite 
 is not present, although there are a few quartz grains of the same size as 
 the g3'psum. Toward the edges the white gj^psite grades into crusty gray 
 silt containing streaks and sjiots of white gypsite up to j'.-inch in diam- 
 eter. Lenses of sand and gravel are to be found within the gypsite, and 
 in places gravel immediately underlies the gypsite. The gypsite bodies 
 lie on clay in which mastodon bones have been found. ^'^ The gypsite at 
 Lost Hills is thought to have formed in basins west of the Los Hills. At 
 a later time uplift of the Temblor Range, which lies to the west, resulted 
 in the cutting of channels through the gypsite bodies and their covering 
 with alluvium. Carryall scrapers of 4-cubie yards capacity are used for 
 mining. 
 
 McKittriek Deposits 
 
 p]xtensive gypsite deposits occur simthwest of McKittriek in the Tele- 
 phone Hills and also east of McKittriek on a hillside facing McKittriek 
 X'alley. Gypsiferous beds in the Maricopa shale and in the Tulare forma- 
 tion have been the source of much of the gypsite,^^ and there are channel 
 deposits of g3'psite also. "When Hess visited the area in 1907 two companies 
 had opened deposits, Abbott and llickox in SWj sec. 30, T. 30 S., R. 22 E., 
 and The California Gypsum and Mineral Company in Si see. 21, T. 30 S., 
 R. 22 B. After being reorganized as the McKittriek Gypsum Company, 
 the Abbott and Hickox property was productive through 1914. Others 
 who reported production of gy])site in the same period or a little later 
 were the McKittriek Extension Oil Company, La Corona Oil and Asphalt 
 Company, and the Kern Countj^ Gypsum Company. 
 
 To ,iudge from analyses published by Hess the gypsite mined prior to 
 World War I Avas comparatively high grade material containing 85 per- 
 cent or more gypsum. Perhaps because of its exhaustion, there was no 
 production from 1922 until, in recent years, the Monolith Portland Ce- 
 ment Company mined gypsite during 1940 and 1941 for use in the manu- 
 facture of Portland cement. Following the closing of their Panoche Hills 
 deposit. Green and Collins produced gypsite in 1941 from a deposit 4 miles 
 
 ^ See also Kings County. 
 
 s'' H. M. Holloway, oral communication. 
 
 ^ Dibblee, T. W., Personal communication. 
 
54 
 
 GYPSUM IN CALIFORNIA 
 
 [Bull. 163 
 
 \^r^ 
 
 7'30" 
 
 NTCPtlOn— CtOLOOICAL ftUBvtY WASMtNOTON O C 
 
 35°15' 
 
 n^'irm" 
 
 1000 
 
 M M fczLJ 
 
 1000 2000 3 000 4000 5000 6000 7000 FEET 
 
 Figure 9. Index map showing locations of gypsite worlcings in the Telephone Hills. 
 
Part 1] GEOix)aY 55 
 
 southwest of McKittrick. The Gypsum Company of California worked a 
 ehannel deposit that crossed State Highway 33 about 1 mile south of 
 McKittrick. The Westorn (Jypsum Company reported production in 1041, 
 1942 and from VJAi) to tlie present. Tiie McKittrirk A<,'riL'ultural Ciypsum 
 Company produced gypsite from 1947 to 1!)50. 
 
 McKittrick Agricultural Gypsum Conipanij Deposit (45). This com- 
 pany operates under lease a deposit in sec. 21, T. 30 S., R. 22 E., that was 
 worked by the California Gypsum and Mineral Company prior to 191U. 
 It may be reached over an extension of E Street, IMcKittrick, which is east 
 «>L" the Southern Pacific station. An average of 3 feet of fairly compact, 
 tan-colored gypsite lies on fine, unconsolidated sand. The company has 
 worked deposits in the Telephone Hills also. 
 
 Telephone Hills Deposit (48). Gypsite occurs at intervals in a valley 
 along the east edge of the Telephone Ilills and about a mile west of State 
 Highway 33. (See fig. 9). "Workings begin just south of the McKittrick- 
 Santa ^Margarita road, and extend soutliward for between 2 and "11 miles. 
 .Vn unimproved dirt road that leaves the Santa ]\Iargarita road 1.1 miles 
 west of its junction with State Highway 33 jia-sses close to most of the 
 gypsite workings. Gypsite has been mined under lease from IMr. Rankin 
 (»f Bakersfield. 
 
 The most northerly workings (number 1, fig. 9) are on the flanks of a 
 lull just south of the Santa IMargarita road and east of a small marsh. 
 This area was worked prior to World "War I by Abbott and Hickox and 
 recently by the IMcKittrick Agricultural Gypsum Company. During 1949 
 a pit 500 feet long, 50 feet wide, and 10 to 15 feet deep was dug at the 
 base of the hill and close to the marsh. Crusty gypsite containing some 
 calcimn carbonate is exposed beneath 10 feet of stony soil. Gypsite extends 
 from the north end of the pit eastward up the hill. East of the pit lenses 
 of fairly hard, tan to white gypsite were mined over an area of several 
 dozen acres. The gypsite grades downward into gravel containing selenite. 
 Areas containing no gypsite are underlain by shale, although in one small 
 area gypsite does rest on shale. The highest part of the hill northeast of 
 the gypsite pit is composed of angular fragments of siliceous shale 
 cemented by caliche. 
 
 The second group of workings (number 2, fig. 9) consists of shallow 
 excavations on a low ridge between two washes and along their banks. 
 This work was done some time ago, and little gypsite remains. 
 
 At the third location (fig. 9) an area of gypsite 100 yards in diameter 
 lias been stripped, and the base of the gypsite is exposed in the north side 
 of the branch gully. There has been little production here. A few inches 
 of stony soil covers 3 feet of fairly hard, fine-grained gypsite. Beneath 
 the gypsite is about 6 feet of gravel composed of angular shale fragments. 
 The gravel in turn rests on steeply dii)ping tan-colored clay shale. 
 
 The fourth location (fig. 9) is at the north end of an extensive group of 
 workings. For a mile to the south the valley is so dug up with prospect 
 trenches and littered with waste piles that the original distribution of 
 the gypsite is obscure. The "Western Gypsum Company has operated at 
 location four. Here gypsite has been mined along the sides of a wash for 
 about half a mile. On the west side of the wash up to five feet of slightly 
 consolidated sand and gravel lie on 3 feet of gj-psite that is soft, fine 
 grained, and gray in color. Downward it grades into gray gypsiferous 
 
56 GYPSUM IN CALIFORNIA [Bull. 163 
 
 sand and clay. Close to the east edge of the workings the wash has exposed 
 the underlying material wliich is shale gravel containing clusters of inter- 
 locking selenite crystals. A trench, made apparently before the other 
 workings, follows the east edge of the valley for about half a mile and 
 extends south into location 5. 
 
 The most recent work in location 5 was done on the west side of the 
 valley b}' the McKittrick Agricultural Gypsum Company, probably be- 
 fore 1948. Stripping on the lower hillsides has exposed gypsite that con- 
 tains some calcium carbonate. In the gypsite area there is no sign of 
 bedrock, but higher on the hillside above the gj'psite there are outcrops 
 of non-gypsiferous, siliceous Maricopa shale of Miocene age. These beds 
 strike approximately north and are steeply dipping. 
 
 The Monolith Portland Cement Company worked a channel deposit in 
 location 6. A crooked excavation about 20 feet deep that followed the 
 channel has removed all the gypsite. On the walls is exposed gray gypsi- 
 ferous clay covered by 10 feet of unconsolidated stony soil. At the south 
 end the channel turns sharply west and terminates in the hillside work- 
 ings of location 7. 
 
 Mining in location 7 may have been done by Green and Collins. No 
 work has been done here for several years, and the access roads and load- 
 ing chutes are in poor repair. Very little gypsite remains here. The gyp- 
 site apparently rested on sand and gravel. 
 
 At location 8 there arc traces of excavations on both sides of State High- 
 way 33, but there is little if any trace of gypsite remaining. The Gypsum 
 Company of California worked a channel deposit here in 1945. 
 
 Packwood Canyon Deposit (47) 
 
 C.L. Fannin ^^ has opened a deposit of gypsite in Paclrvs'ood Canyon in 
 sec. 9, T. 27 S., R. 18 E., MDM. It may be^reached from a point on U.S. 
 Highway 466 6.9 miles west of Blackwell's Corner over an improved 
 gravel road four miles long. Gypsite has formed in a shallow basin where 
 two intermittent streams join before flowing northeastward through a 
 relatively steep and narrow valley. The bedrock is steeply dipping Mc- 
 Donald shale, a member of the upper Miocene Monterey formation.'*" 
 In the basin from a few inches to 2 feet of silt lies on soft white gypsite 
 that contains a little calcium carbonate. Downward the white gypsite 
 grades through impure gray gypsite containing quartz grains and rock 
 fragments to hard gypsiferous clay containing much calcium carbonate. 
 Around the margins of the basin the streams have cut through the gypsite 
 into stream gravel leaving a flat-topped island in the middle of the basin. 
 In 1948 several acres had been stripped, and the gypsite was being pre- 
 pared with a harrow for removal with a carryall scraper. 
 
 Kings County Deposits 
 Avenal Gap Mine" (50) 
 
 The Avenal Gap mine of H. M. Holloway, Inc., is in Kettleman Plain 
 in sees. 2, 3, 11, T. 24 S., R. 18 E., MDM. It may be reached over a paved 
 road 1.7 miles long that begins on State Highway 33 2.4 miles south of 
 the junction of State Highways 33 and 41. Here a gypsite body, probably 
 
 8» See also San Luis Obispo County. 
 
 *o Heikkila, H. H., and MacLeod, G. M., Geologry of tlie Bitterwater Creek area, Kern 
 
 County, California : California Div. Mines, Special Rept. 6, plate 1, 1951. 
 *i See also Kern County, 
 
DIVISION OF MINES 
 
 BULLETIN 163, PLATE 37 
 
 
 
 
 >». 
 
 GYPSUM QUARRY, MONOLITH PORTLAND CEMENT COMPANY 
 
 Quatal Canyon. Clay beds above and beneath the gypsum are visible. Some clay 
 interbedded with gypsum occurs half way up the face. 
 
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DIVISION OP MINES 
 
 BULLETIN 163, PLATE 42 
 
 # 
 
 » 
 
 i 
 
 CRIFFIX GYPSITE DEPOSIT 
 
 Tumey Oulch, Fresno County. Gypsite is ground in a hammer mill to remove 
 
 lumps and loaded into trucks through the chute in the foreground. A prospect 
 
 trench is on the hillside above the hammer mill. 
 
DIV'ISION OF MIN'ICS 
 
 BULLETIN IC?,, I'LATK 43 
 
 'I: 
 
 ^ 
 
 
 r jV, 
 
 ^■'- <> 
 
 
 SOLUTION CAVITY IN GYPSITE 
 Pacific Gvpsite Companv depo.sit, Kern Lake, Kern County. A solution cavity 
 occurs in "the pit floor. Note the track marks of the carryall scraper used to mine 
 
 the gypsite. 
 

 2 
 
 73 
 
 o 
 
 >^ 
 
 o 
 
 h-t 
 
 P 
 
Parti] GEOLOGY 57 
 
 of the lake margin typo, lies with a sliarp but irregular contact on sandy- 
 clay. Of a total average thickness of feet, tlic upper 2 feet is a hard gray 
 material composed of silt containing streaks and spots of finely divided 
 gj'psum. The lower 4 feet is fine-grained, soft, yellow'ish-white gypsite 
 that contains a little calcium carbonate. Throughout the gypsite body 
 lenses of unconsolidated sand are to be found; and there are tunnellike 
 holes 1 or 2 feet in diameter, some of which are partly filled with sand. 
 Two to three feet of sandy soil lies on the gypsite. The gypsite surface is 
 irregular and is marked by what appear to be water-cut channels 1 foot 
 wide and 9 inches deep. Carryall scrapers are used. 
 
 Los Angeles County Deposits 
 Palmdale Deposits (56) 
 
 Gvpsite deposits half a mile southwest of Palmdale in N"W| sec. 35, T. 
 n X*. R. 12 W., SP,:\r have been described by Iless and by Simpson.''^ 
 Evidences of open pit operations are also to be seen in SE j sec. 3-i, T. 6 
 X.. R. 12 W., Sim. :\nning was begun in 1892 by the Alpine Plaster Com- 
 pany, and in 1910 both this company and the Fire Pulp Plaster Company 
 liad mines and calcining plants at Palmdale. Operations were abandoned 
 by 1915 when the easily obtainable gypsite had been exhausted. In 1948 
 the only traces remaining of the extensive operations w'cre some partly 
 filled open cuts. 
 
 The gypsite occurred on a low ridge south of Palmdale which may be 
 reached from a track that turns west from U.S. Highway G just south of 
 the railroad wye at Palmdale. Gypsite is associated with a gypsiferous 
 shale member of the Escondido (Vasquez) formation that Simpson was 
 able to trace for more than 8 miles east and west of Palmdale. Crystalline 
 Q-ypsum in beds an inch or two thick alternates with crumpled beds of 
 lirown sliale. Gypsite formed beds 2 to 10 feet thick on the beveled edges 
 of the gypsiferous shale. 
 
 Merced County Deposits 
 A. D. Sousa Deposit^» (59) 
 
 In St'ptcmber A. D. Sousa was developing a gypsite deposit in X^E} 
 sec. 2, T. 12 S., R. 10 E., :\ID:\I. It may be reached by a steep but graded 
 road that begins where the road running south from Los Banos turns 
 southeastAvard to parallel the foothills. The gypsite is derived from the 
 Kreyenhagen formation wliicli in this area consists of beds of diatomite 
 and marl that dip northeast toward the San Joaquin Valley. The marl 
 is cut by closely spaced satin spar veins up to 4 inches thick. 
 
 The Sousa deposit lies on a flat-topped ridge underlain by the Kreyen- 
 hagen formation. Gypsite of uniform but comparatively low grade forms 
 a flat-lying deposit on the beveled edges of the gypsiferous bedrock. It 
 is planned to ship material assaying 40 percent gypsum. 
 
 Riverside County Deposits 
 Corona Deposits 
 
 Four miles south of Corona in the foothills of the Santa Ana IMoun- 
 tains there is a 2] -mile belt that contains gypsite of comparatively low 
 grade. Although the gypsum content is only between 20 and 30 percent, 
 
 "Hess, p. L,.. California, in Stone, R. W., and others, Gypsum deposits of the United 
 States: U. S. Oeol. Survey Bull. fi97, pp. 75, 76, 1920. 
 Simpson, E. C., Mines and mineral resources of the Elizabeth Lake quadrangle, Cali- 
 fornia: California Div. Mines Kept. 30, p. 412, 1934. 
 
 " See also Fresno County. 
 
 10—58771 
 
58 GYPSUM IN CALIFORNIA [Bllll. 163 
 
 the material carries enough iron and lime to make it of value as a soil 
 conditioner. An appreciable tonnage has been mined in liagador Canyon, 
 Gypsum (Main Street) Canyon, and Eagle Canyon and from the inter- 
 vening ridges. Most of the mining took place from 1909 to 1919 and from 
 1924 to 1934 ; there have been no shipments since that time. 
 
 Among those who have reported production of gypsite are the Soil 
 Tone Company and E. R. Xonhoff from Hagador Canyon; G. W. Lord 
 from Gypsum (Main Street) Canyon; and the Amestoy Mineral Fer- 
 tilizer Company, Natural Fertilizer Company, and Mineral Fertilizer 
 Company from Eagle Canyon. Levi Katz and Floyd Shoemaker mined 
 some gypsite from the Frazer property in Eagle Canyon during 1944."*^ 
 
 The deposit in Hagador Canyon (66) may be reached from a dirt road 
 turning south from Chase Drive just east of iMangular Avenue, Corona. 
 A foot path leads to the deposit, about a mile from the junction of Tin 
 Mine and Hagador Canyons. A road from the south end of Main Street 
 formerly led to the Gypsum Canyon deposit (65), but it is no longer 
 passable for vehicles. The deposits have been opened by small cuts, shal- 
 low pits, and short tunnels. 
 
 In Gypsum and Hagador Canyons the country rock is a hard gray, 
 block}^ andesite porphyry of the Santiago Peak volcanics that has been 
 cut by shear planes that strike northeast and dip steeply northwest. 
 Along the sheer planes are zones of hydrothermal alteration where the 
 porphyry has been kaolinized and stained with limonite. Closely spaced 
 satin spar veinlets run in all directions through the altered rock. Ap- 
 parently both the gypsum-bearing altered rock and gypsite derived from 
 
 it were mined. 
 
 San Luis Obispo County Deposits 
 
 Carrisa Mine (95) 
 
 The Carrisa gypsite mine, located in see. 21, T. 30 S., R. 20 E., was 
 operated by V. C. Hatle.y and C. L. Fannin during 1947 but was idle 
 in December 1948. The mine may be reached from the road to Soda Lake 
 that leaves State HighAvay 178, 18 miles west of ]\IcKittrick. The gypsite 
 here has been derived from the upper Pliocene McKittrick formation. 
 
 The deposit consists of at least three elongated, flat-lying lenses of 
 gypsite that lie along an approximately east-west line extending for 
 three quarters of a mile from the lower slope of the Temblor Range 
 toward the Carrizo Plain. The easternmost and largest lens is about 500 
 yards in diameter, while the most western and smallest is less than 100 
 yards wide. Between the three lenses there is little if any gypsite. 
 
 Gypsite crops out in the higher parts of the deposit, but on the lower 
 slopes it is covered with 12 to 14 inches of stony soil. In general the 
 upper 2 feet of the gypsite is a relatively clean, earthy, cream-colored 
 material that grades dowuAvard into gypsite that contains sand and 
 fine-grained gravel. In places the sandy gypsite rests on gravel contain- 
 ing ^-inch selenite fragments, but in other places at least locally it lies 
 on soft clay shale. 
 
 Shandon Deposit (97) 
 
 The Shandon deposit, which has been operated under lease by C. E. 
 Vanderford and is now worked by the owner, L. L. Stvles, is in sec. 21, 
 T. 26 S., R. 15 E., SBM, just east of Shandon on U. S. Highway 466. 
 
 "Tucker, W. B., and Sampson, R. J., Mineral resources of Riverside County: California 
 Div. Mines Kept. 41, p. 168, 1945. 
 
Part 1 ] OEOLOGY 59 
 
 This is a lenticular deposit of the lake margin 1yi)e 4 feet thick, 500 
 yards long, and 200 yards wide. At the end of 1948 gypsite had been 
 mined from the north side of the higiiway, but it exists on the south side 
 also. Tliere is no overburden except a few inches of earth, and the deposit 
 lies on clay. The material mined, which is guaranteed to contain 70 per- 
 cent gypsum, is a tan-colored, earthy material that contains an appreci- 
 ; able amount of calcium carbonate. A test cut just north of the lens 
 encountered gray silt containing streaks and spots of fine-grained 
 
 gypsum. 
 
 Ventura County Deposits 
 Fillmore Deposit (106) 
 
 A gvi)sitc ilcposit formerly worked by the Sunset Plaster and Cement 
 Company of Fillmore is on Oak Ridge in SE^ sec. 7, T. 3 N., R. 19 W., 
 SBM. An old road impassable for vehicles runs to the deposit from 
 State Highway 28 at the point where the highway joins Grimes Canyon, 
 (iypsite has not been mined since 1914. The principal mine opening is 
 an open cut with face about 200 feet long and 100 feet high, and there 
 are at least four smaller cuts. 
 
 Bedrock here is the Modelo shale.^^ "Chalky," diatomaceous, organic, 
 and clay sliales of this formation dip steeply southAvest. Near the deposit 
 the organic shale has been burned, perhaps by spontaneous combustion, 
 to a vesicular, brick-red material resembling lava. Satin spar veinlets 
 up to an eighth of an inch wide cut the shales. Pockets of gypsite have 
 foriiK^d on the outcrop and extend as much as 30 feet into the bedrock 
 iluwu tiie dip. Little gypsite remains. 
 
 ORIGIN OF GYPSUM 
 
 "With the exception of gypsite and some hydrothermal vein and re- 
 ))lacement deposits of minor economic interest, gypsum deposits are 
 believed to be chemical jn'eci])itates that have formed from saline solu- 
 tions. Playa deposits undoubtedly are, but the processes involved in the 
 formation of the thick beds of rock gypsum are not readily apparent. 
 Xo entirely satisfactory hypothesis for the origin of such deposits has 
 been prt)posed. 
 
 I When saline water is evaporated, in general the least soluble salts 
 precipitate first and leave the more soluble ones in the mother liquor. 
 The very soluble bittern salts, which are usually complex salts, precipitate 
 only after complete evaporation. The precipitation of a salt is greatly 
 influenced by temperature and the concentration of other salts in the 
 
 I solution. The behavior of systems of mixed salts has been determined 
 for only a comparatively small number of systems. 
 
 Theoretically the evaporation of a body of saline water results in 
 separate layers of limestone, gypsum, common salt and bittern salts that 
 are deposited in inverse order of their solubility, but the complete se- 
 quence rarely if ever occurs in nature. Bristol Lake possesses some of 
 the ideal features, for gypsum and salt occur in separate parts of the 
 lake, while the brine associated with the salt is high in calcium cljloride.-"' 
 Rock gypsum is, however, greatly different from the loosely knit mesh 
 of large gypsum crystals mixed with salt and silt that characterizes the 
 
 « Kew, W. S. "W.. Geology and oil resources of a part of Los Angeles and Ventura Coun- 
 ties, California: U. S. Geol. Survey Bull. 753, p. 61, 1924. 
 
 •« Gale, H. S., Geologv of the saline deposits of Bristol Dry L.ike, San Bernardino County, 
 California : Calif. Div. Mines Special Rept 13, 21 pp., 1951. 
 
60 GYPSUM IN CALIFORNIA [Bull. 163 
 
 playa deposits. Except for the Avawatz Mountains deposits the Cali- 
 fornia rock gypsum deposits are not associated with salt or other salines. 
 Limestone is not present except in the pre-Tertiary deposits although 
 most specimens contain 1 percent or less of calcite as scattered grains 
 0.001 inch in size. Moreover, the gypsum itself of the California deposits 
 is of great uniformity and contains no more than traces of salt and other 
 very soluble salines. Branson ^" lias calculated that 0.7 feet of gypsum 
 would be deposited from 1000 feet of sea water evaporated to the satura- 
 tion point of sodium chloride. Even if sea water were first concentrated to 
 the saturation point of gypsum and then evaporated it would require 
 a basin 11,500 feet deep to deposit 40 feet of pure gypsum without salt. 
 Apparently either the water from wiiich thick gj'psum deposits precipi- 
 tated contained only calcium sulfate or else in some way it remained 
 unsaturated with the other salts normally found in saline water. 
 
 In order to explain the formation of gypsum in basins of reasonable 
 depth a number of hypotheses have been proposed. The bar theory of 
 Ochsenius,'*^ which supposes a basin separated from the open sea by a 
 bar of sufficient height to allow fresh supplies of sea water to come in, 
 explains the formation of salts but not their separation. Branson ^^ 
 imagined a series of connecting basins like those of a solar salt works 
 in which salts of differing solubility would be separately precipitated. 
 Others have suggested the leaching of thin deposits and the subsequent 
 reprecipitation of gypsum in deeper basins,^'' or the mechanical concen- 
 tration by currents of already precipitated gypsum. 
 
 Branson 's modified bar hypothesis seems to fit some of the California 
 deposits, perhaps the Death Valley deposits most clearly. Assuming cli- 
 matic conditions slightly more humid than those of today, the region was 
 probably supplied with saturated saline water from which the slightly 
 soluble calcium carbonate had already been precipitated. Both the China 
 Ranch and Avawatz Mountains deposits formed in temporary saline lakes 
 that had restricted outlets. Evaporation caused the water to be saturated 
 with gypsum but not with sodium or potassium salts. These more soluble 
 salts, still in solution, escaped through the outlet and eventually reached 
 the floor of Death Valley. Although it is difficult to reconstruct the pre- 
 faulting conditions at the Avawatz Mountains deposits, the gypsum and 
 salt were probably separated hy sediments. After the gypsum precipita- 
 tion ceased and the gypsum was buried, salt precipitating conditions 
 prevailed. 
 
 The modified bar hypotheses applies also the Cuyama Valley deposit. 
 According to Dibblee ^^ the sediments that contain the gypsum are non- 
 marine sediments that grade northwestward into marine sediments. Per- 
 haps a temporary basin close to the shore was fed by pre-concentrated 
 saline water from the land area to the southeast. The brown shales that 
 enclose the gypsum suggest such a lake. In this case the overflow of water 
 high in soluble salts flowed into the sea and was lost. 
 
 " Branson, B. B., Origin of thick gypsum and salt beds : Geol. Soc. America Bull., vol. 2G, 
 
 p 232 1915 
 « Grabau,' A. V^'., Principles of salt deposition, pp. 128-130, New York, McGraw-Hill Book 
 
 Co., 1920 (.summary in Ene:lisli). 
 ^» Branson, E. B., op. cit. pp. 231-242. ^ , o, 
 
 M Wilder, F. A., Some conclusions in regard to the origin of gypsum : Geol. Soc. America 
 
 Bull., vol. 32, pp. 3S5-39-1, 1921. 
 M Dibblee, T. W., Jr., Personal .communication. 
 
< 
 
 n 
 
 
 M 
 
 
 o 
 
 m 
 
 > 
 Q 
 
DIVISION OP MINES 
 
 BULLETIN 163, PLATE 46 
 
 ^1. AVENAL (JAP GYPSITE MINE 
 Kings County. Mining gypsite with oarryall scraper. Photo by J. IV'. Vernon. 
 
 
 B. CARISSA GYPSITE MINE 
 Carrizo Plain, San Luis Obispo County. Truck loading chute. 
 
DIVISION OF MINKS 
 
 BULLETIN 163, PLATK 4' 
 
 
 
 L_ 
 
 005 In. 
 
 I 
 
 PHOTOMICROGRAPH OF ALABASTER 
 
 Exhibiting granoblastic texture. Frenchman's Point deposit, Cuyama Valley. 
 
 Cros.sed nicols. 
 
DIVISION OP MINES 
 
 BULLETIN 163, PLATE 48 
 
 
 
 005 
 
 in. 
 
 PHOTOMICROGRAPH OF CJYPSUM 
 Exhibiting fibrous texture. Fish Creek Mountains deposit. Crossed nicols. 
 
DIVISION' OF MINES 
 
 BULLETIN 1G3. PLATE 49 
 
 
 
 
 L- 
 
 01 in. 
 
 I 
 
 PHOTOMICROOKAPH OF PORPHYKITK" CYPSUM 
 
 Utah Construction Company <iuarry, Little Maria Mountains. Large euhertral to 
 
 subhedral gypsum crystals in a granoblastic groundmass. Crossed nicols. 
 
DIVISION OF MINES 
 
 BULLETIN 163, PLATE 50 
 
 
 ^\ 
 
 /"x 
 
 /^ms^' 
 
 '4^. 
 
 
 
 
 
 01 in. 
 
 — I 
 
 PHOTOMICROGRAPH OF GYPSUM AND ANHYDRITE 
 Utah Construction Coinj^any Quarry, Little Maria Mountains. Fibrous gypsum fills 
 cracks between anhydrite that has well developed polysynthetic twinning in two direc- 
 tions. Plain light. 
 
DIVISION or-' MINI'.S 
 
 HIM.LKTI.N' ir,.!, I'LATIO ', 1 
 
 ,V^. -- 
 
 
 
 L. 
 
 005 In. 
 
 — I 
 
 PHOTOMICROGRAPH OF FIHROl'S CYPSIM 
 And anhyilrite, I'tah ConstriU'tion cinarry, T-ittle Maria Mountains. Crossed niools. 
 

 E 
 
 m 
 
 .; 
 
 '■■ '!' 
 
 0. 
 
 ^^3 
 
 
 o 
 
 •^-^•^4^. '^^ 
 
 v>. 
 
 *i 
 
 Vi,*ll> 
 
 
 ►7 "^ 0; 
 
 ^ C p 
 
 i Ji 
 
Parti] GEOLOGY 61 
 
 With the P^ish Creek Mountains deposit the iiiodiheil bur liypotheses is 
 k^ss clear. The absence of any great (juantity of fine sediments is notiee- 
 abh\ wliile there is a very great thickness of fanlike t'(mgionierate. Per- 
 haps a strnctnral basin -was formed whicli was jtaiiially fdled with de- 
 trital material from the surrounding iiigliland of granitic and metamor- 
 phic rock. The abruptness of the transition from conglomerate to gypsum 
 suggests that the basin was quite suchlenly filled with saline water already 
 concentrated to the saturation point of gypsum. Either the supply of 
 clastic material almost entirely ceased while the more than 100 feet of 
 gypsum formed, or else the gypsum precipitated extremely rapidly com- 
 pared to the rate of accumulation of the arkosic sandstone that preceded 
 and succeeded the gypsum-jn-ecipitating interval. Because large deposits 
 of salt have not been found in the 8alton Sea region it seems likely that 
 most of the salt a.ssociated with the gypsum escaped in solution, perhaps 
 to the Gulf of California. 
 
 A lagoon origin for the pre-Tertiary deposits is not obvious because the 
 evidence of the topography has disappeared and even the relative ages of 
 the rock units are obscure. Harder ''- believes that these deposits formed in 
 the deep waters of saline lakes in which uniform conditions of sedimen- 
 tation prevailed. Presumably the region was later subjected to mild re- 
 gional metamorphism that changed any calcium sulfate existing as 
 gypsum to anhydrite, shale to schist, sandstone to quartzite, and re- 
 crystallized tlie limestones. Mixtures of schist and gypsum resulted from 
 the metamorphism of impure gyjisum and gypsiferous clay. A typical 
 specimen of impure gy])suni from a waste layer in the TTtah Construction 
 ' 'ompany ([uarry consists of lenses of gypsum I to 1 inch long sei)arated 
 by green layers of micaceous minerals that are broken and bent around 
 the gypsum lenses. Small structures in gypsum containing argillaceous 
 impurities at tlie Avawatz JMountaius are much the same. 
 
 The major difference between the pre-Tertiary and the Tertiary gyp- 
 sum deposits is the character of the associated sediments. The Tertiary 
 deposits originated in temporary saline lakes that formed in areas that 
 were land before and after gypsum deposition, whereas the pre-Tertiary 
 deposits are associated with marine sediments, and gypsum formation was 
 preceded and succeeded by marine conditions. 
 
 It is possible, although less likely, that in the pre-Tertiary deposits the 
 gypsum zones may be certain limestone beds that have been replaced by 
 calcium sulfate. The magnesium of the tremolite, which is widely distrib- 
 uted in both the gypsum zones and the green schistose rocks, could have 
 been introduced at the same time as the calcium sulfate. 
 
 Gypsum-Anhydrite Problem 
 
 Gypsum is almost always associated with anhydrite, and in most de- 
 posits, including those in California that have been developed in depth, 
 gypsum grades downward into anhydrite. In the extensively explored 
 deposits of New York. Michigan, and Ohio this gradational contact is 
 parallel to the present surface and at a depth of from 100 to 300 feet.^^ 
 As far as can be told from the limited data available the same conditions 
 are true in the Fish Creek Mountains deposit. In the Little Maria Moun- 
 
 •'■2 Harder, E. C, The gvpsum deposits of the Palen Mountains, Riverside County, Cali- 
 fornia : U. S. Geol. Survey Bull. 430, pp. 413, 414, 1910. 
 ^Newland, D. H., Relation of gypsum supplies to mining: Am. Inst. Min. Met. Eng., 
 . Trans, vol. 66, pp. 92-94, 1922. 
 
 12—58771 
 
62 GYPSUM IN CALIFORNIA [Bull. 163 
 
 tains where gypsum and anhydrite are more intimately mixed, the pro- 
 portion of gypsum is proportional to the extent of open fraeturing in 
 the enclosing rocks.^^ 
 
 There lias been lack of agreement as to whether calcium sulfate precipi- 
 tates as anhydrite and is hydrated by ground water or whether gypsum is 
 converted to anhydrite by heat and/or pressure when it is buried. The 
 conditions under which gypsum and anhydrite precipitate have been 
 studied in the laboratory. Posnjak '^•^ concluded that the widely accepted 
 data of Van't Hoff are incorrect. His experiments showed that from a 
 solution of calcium sulfate in water gypsum precipitates below 42° C 
 (108° F) and anhydrite above that temperature. The presence of other 
 salts lowers this temperature. "When sea water evaporates at 30° C about 
 half of the calcium sulfate present precipitates as gypsum, and when the 
 salt content has risen to 4.8 times normal, the calcium sulfate remaining 
 precipitates as anhydrite. He concludes that if a deposit of anhydrite is 
 assumed to have formed at less than 42° C at least part of it must be 
 secondary. That actually some anhydrite is primary is suggested by the 
 presence of small quantities of anhydrite among the minerals of playas."*^" 
 
 Microscopic Evidence. Among the first to apply the petrographic 
 microscope to the gypsum-anhydrite problem and one of the few to de- 
 scribe these minerals in thin section is A.F. Rogers.^'^ From a study of 
 specimens of gypsum and anhydrite from many parts of the United States 
 he concludes that most gypsum is a hydration product of anhydrite. His 
 conclusions are based not only on the relations between gypsum and 
 anhydrite as seen in thin section but on differences of the gypsum's 
 texture as well. 
 
 Gypsum in Thin Section. For convenience the textures recognizable 
 in the California specimens are summarized here. The first, corresponding 
 to Rogers' hydration structure, consists of intricately interlocking equidi- 
 mensional anhedra that range from 0.002 to 0.02 inch in size. Optically 
 the grains are unoriented, and each grain has a narrow extinction angle. 
 A second texture megascopically is a granular aggregate of grains 0.05 
 inch in size. Under the microscope each grain is seen to be composed of 
 minute, nearly parallel fibers of gypsum. A third texture consists of 
 poorly defined areas, often filled with anhydrite inclusions, that have a 
 wide extinction angle. Such grains liaA^e lower relief and birefringence 
 than do those of the first texture described. 
 
 In the present study Rogers' evaportion structure, or the texture of 
 gypsum formed by direct precipitation from saline water, was not recog- 
 nized. His illustration shows large interlocking euhedral and subhedral 
 crystals. It is a photomicrograph of gypsum from a deposit near King 
 City ; one of the few that Rogers believes to be primary. It is to be noted 
 that Avhile the specimen from Mule Shoe Ranch, described earlier, does 
 contain a few euhedral crystals the texture is predominately the hydra- 
 
 ^ Conwav, C. L., Personal communication. 
 
 ^Posnjak, E., The system, CaSoi-HsO : Am. Jour. Sci., 5th ser., vol. 35-A, pp. 247-272, 
 
 1938. 
 Deposition of calcium sulfate from sea water: Am. Jour. Sci., vol. 238, pp. 559-568, 
 
 1940. 
 5« Hanks, H. G., On the occurrence of hanksite in California : Am. Jour. Sci., 3rd series, 
 
 vol. 37, p. 66, 1889. 
 S7 Rogers, A. F., Notes on the occurrence of anhydrite in the United States : School of 
 
 Mines Quarterly, Columbia Univ., vol. 36, pp. 123-142, 1915. 
 
Part 1 ] GEOLOGY 63 
 
 tiou kind. Tho Qiiatal Canyon <rypsum also contains a small proportion of 
 euliotlral to subhcdral crystals. 
 
 Conclusions. The present study confirms Rojrers' conclusions that 
 mo.st gypsum is a rei)lacement of anhydrite. The veinlike penetrations of 
 gypsum into anhydrite and the corroded remnants of anhydrite present 
 in many specimens of gypsum show this. 
 
 With regard to the texture of gypsum, it is unlikeh' that Rogers' hy- 
 dration structure is diagnostic of gypsum derived from anhydrite. In the 
 Little Maria Mountains the gypsum that actually penetrates between 
 anhydrite grains has fibrous rather than hydration texture, while pure 
 gypsum in that area is in well-developed euhedral crystals. It is possible 
 tliat the hydration texture is caused by recrystallizatiou because there is 
 a striking resemblance between it and that of marble or metamorphic 
 (juartzite. 
 
 The significance of the fibrous texture is not clear. The Fish Creek 
 Mountains gypsum, which is fibrous, is tightly folded although the en- 
 closing rocks are not. Perhaps fibrous gypsum forms when the gypsum 
 recrystallizes under stress. Impure gypsum from Quatal Canyon is fib- 
 rous, and so is pre-Tertiary gypsum that contains schist, limestone, or 
 anhydrite. Possibly stress was caused by the interference of the impuri- 
 ties with the growth of the gypsum crystals. 
 
PART 2 
 
 MINING, PROCESSING 
 AND MARKETING OF GYPSUM 
 
PART 2 
 
 CONTENTS 
 
 Page 
 
 Mining 67 
 
 History 67 
 
 Mining methods 72 
 
 Beneficiation 74 
 
 Processing 76 
 
 Agricultural gypsum 76 
 
 Portland cement retarder 84 
 
 Calcination of gypsum ^ 85 
 
 Calcium sulfate and its hydrates 85 
 
 Commercial calcination 86 
 
 Finishing the plaster 88 
 
 Anhydrous plasters 89 
 
 Marketing 90 
 
 Gypsum products 90 
 
 Building jilasters 90 
 
 Prefabricated products 92 
 
 Reinforced gypsum concrete 94 
 
 Industrial plasters 94 
 
 Minor uses of gypsum 96 
 
 Uses of anhydrite 97 
 
 Gypsum markets 98 
 
 Gypsum plants in California 101 
 
 (60) 
 
Part 2] MINING, PROCESSING, AND MARKETING 67 
 
 MINING 
 History of Gypsum Production in California 
 
 At one time or another most of California's gypsum deposits have 
 attracted miners, and the records contain the names of scores of operators 
 wlio worked tliem. Few of these enterprises, however, endured for longer 
 tlian 5 years, and of these not many contributed a significant proportion 
 of the current production. The California gypsum industry has, how- 
 ever, from the very beginning been dominated by a major producer who, 
 with one or two comiietitors. accounted for three quarters of the produc- 
 tion at tlie time tliey were active. It is possible to define five overlapping 
 periods during which the gypsum industry was centered in one deposit 
 and one comi)any. In general the end of a period came when the dominat- 
 ing deposit became exliausted or was no longer able to supply the con- 
 stantly rising demand for gypsum. 
 
 The first period, which includes the very beginning of the industry in 
 California, came to an end about 1900. Production average about 2500 
 tons a year. It has been stated ^^ that the earliest use for gypsum in 
 California was for agriculture. As early as 1875, however, the Golden 
 Gate Plaster ]Mill of Lucas and Company was in operation at San Fran- 
 cisco. Prior to that time calcined gypsum was brought into California 
 by ship. John Lucas, who had been a calciner for a New York firm, came 
 to California in 1865 and began experimenting with crude gypsum from 
 a number of deposits. Before 1880 Lucas and others were importing crude 
 gypum from Lower California, probably San Marcos Island. Then in 
 1880 Lucas and Company leased a deposit near Point Sal, Santa Barbara 
 County and develojicd the Point Sal mine, the first important California 
 gypsuiii protlucer. Tlie gypsum, which occurred as bunches and veins in 
 clay shale, was mined from tunnels and loaded on ships at a landing 
 near Point Sal, a mile or two from the mine. An estimated thousand tons 
 were mined in the first four years. The mine was closed, however, in 
 1889, and by 1895 the workings were inaccessible. The Lucas Company 
 continued until about 1900 when fire destroyed the mill in San Francisco. 
 
 Meanwhile in 1884 agricultural gypsum was being ground at a mill 
 in Los Angeles. Jn 1890 and for several years after that Captain Faunt- 
 leroy mined agricultural gypsum from the Cottonwood Creek deposit 
 near Bakersfield. Hall, Doverall, and Lavelle in 1892 opened a deposH 
 near Coalinga which produced agricultural gypsum until about 1897. 
 In addition a number of other deposits which later assumed some impor- 
 tance were first Avorked in the 1890 's. 
 
 The second period, from 1900 to about 1908, is largely the history of 
 tlie Alpine Pla.ster Company with mines at Palmdale. The total California 
 production had by then risen to an average of 10.000 tons a year. The 
 Alpine Plaster Company as early as 1892 had a calcining plant in Los 
 Angeles for treating crude gypsum mined at Pahndale. The output of 
 the Los Angeles mill for a single month in 1893 was as follows : ^'^ 
 
 Value per ton 
 Tons f.o.b. I^s Angeles 
 
 Plaster of Paris 15 $18.00 
 
 Wall pla.'^ter 20 $11.00 
 
 "Fertilizer" 100 $7.00 
 
 ^ Santmyers, R. M., Development of the gypsum industry by states : U. S. Bur. Mines Inf. 
 
 Circ. 6173, pp. 6-9, 1929. 
 so Gypsum : CaUfornia Mln. Bur. Kept. 12, p. 324, 1893. 
 
68 
 
 GYPSUM IN CALIFORNIA 
 
 [Bull. 163 
 
 GYPSUM PRODUCTION IN CALIFORNIA 
 
 Year 
 
 Short 
 tons 
 
 Value 
 
 Average 
 value 
 
 Year 
 
 Short 
 tons 
 
 Value 
 
 Average 
 value 
 
 1887 
 
 2,700 
 
 S27,000 
 
 
 1917 
 
 30,825 
 
 $56,840 
 
 
 1888 
 
 2,500 
 
 25,000 
 
 
 1918 
 
 19,695 
 
 37,176 
 
 
 1889 
 
 3,000 
 
 30,000 
 
 > $10.00 
 
 1919 
 
 19,813 
 
 50,579 
 
 [ $2.60 
 
 1890 
 
 3,000 
 
 .30,000 
 
 1920 
 
 20,507 
 
 92,. 5.35 
 
 
 1891 
 
 2,000 
 
 20,000 
 
 
 1921 
 
 37,412 
 
 78,875 
 
 
 1892 
 
 2,000 
 
 20,000 
 
 
 1922 
 
 47,084 
 
 188,336 
 
 
 1893 
 
 1,620 
 
 14,280 
 
 
 1923 
 
 86,410 
 
 289,136 
 
 
 1894 
 
 2,446 
 
 24,584 
 
 9.70 
 
 1924 
 
 25,. 569 
 
 .53,210 
 
 [ 2.58 
 
 1895 
 
 5,158 
 
 51,014 
 
 1925 
 
 107,613 
 
 172,444 
 
 
 1896 
 
 1,310 
 
 12,580 
 
 
 1926 
 
 114,868 
 
 211,337 
 
 
 1897 
 
 2,200 
 
 19,250 
 
 1927 
 
 94,630 
 
 292,090 
 
 
 1898 
 
 3,100 
 
 23,000 
 
 
 1928 
 
 104,790 
 
 200,. 567 
 
 
 1899 
 
 3,663 
 
 14,950 
 
 [ 6.87 
 
 1929 
 
 140,844 
 
 396,951 
 
 [ 2.43 
 
 1900 
 
 2,522 
 
 10,088 
 
 
 1930 
 
 116,865 
 
 243,507 
 
 
 1901 
 
 3,875 
 
 38,750 
 
 
 1931 
 
 88,854 
 
 199,198 
 
 
 1902 
 
 10,200 
 
 53,500 
 
 
 1932 
 
 46,867 
 
 93,818 
 
 
 1903 
 
 6,914 
 
 46,441 
 
 
 1933 
 
 59,235 
 
 120,451 
 
 
 1904 
 
 8,350 
 
 56,592 
 
 [ 5.26 
 
 1934 
 
 .58,149 
 
 113,606 
 
 [ 2.03 
 
 1905 
 
 12,859 
 
 54,. 500 
 
 
 1935 
 
 70,833 
 
 151,807 
 
 
 1906 
 
 21,000 
 
 69,000 
 
 
 1936 
 
 143,549 
 
 282,703 
 
 
 1907 
 
 8,900 
 
 .57,700 
 
 
 1937 
 
 186,160 
 
 384,431 
 
 
 1908 
 
 34,600 
 
 155,400 
 
 
 1938 
 
 161,996 
 
 327,821 
 
 
 1909 
 
 30,700 
 
 138,176 
 
 [ 4.31 
 
 1939 
 
 219,672 
 
 437,343 
 
 [ 1.99 
 
 1910 
 
 45,294 
 
 129,1.52 
 
 
 1940 
 
 314,843 
 
 599,944 
 
 
 1911 
 
 31,457 
 
 101,475 
 
 
 1941 
 
 432,784 
 
 854,184 
 
 
 1912 
 
 37,529 
 
 117,388 
 
 
 1942 
 
 425,268 
 
 791,892 
 
 
 1913- - 
 
 47,100 
 
 135,050 
 
 
 1943 
 
 475,967 
 
 916,883 
 
 
 1914 
 
 29,734 
 
 78,375 
 
 [ 2.53 
 
 1944 
 
 558,488 
 
 949,833 
 
 I 2.00 
 
 1915 
 
 20.200 
 
 48,9.53 
 
 
 1945 
 
 442,133 
 
 954,696 
 
 
 1916 
 
 33,384 
 
 59,533 
 
 
 1946 
 
 618,007 
 
 1,431,884 
 
 
 
 
 
 
 1947 
 
 811,798 
 
 1.996,157 
 
 
 
 
 
 
 1948 
 
 962,038 
 
 2,3.54,.390 
 
 [ 2.45 
 
 
 
 
 
 1949 
 
 753, .581 
 
 1,852,452 
 
 
Part 2] 
 
 MINING, PROCESSING, AND MARKETING 
 
 (iO 
 
 GYPSUM PRODUCTION (SHORT TONS) BY COUNTIES 
 
 Year 
 
 1880-1889. 
 
 1890 
 
 1891 
 
 1892 
 
 1893 
 
 1894. 
 
 1895 
 
 1896 
 
 1897. 
 
 1898 
 
 1899 
 
 1900 
 
 I'.tOl 
 
 1902 
 
 1903 
 
 1904 
 
 1905 
 
 1906 
 
 1907 
 
 1908 
 
 1909 
 
 1910 
 
 1911 
 
 1912 
 
 1913 
 
 1914 
 
 1915 
 
 1916 
 
 1917 
 
 1918 
 
 1919 
 
 1920 
 
 1921 
 
 1922 
 
 1923 
 
 1924 
 
 1925 
 
 1926 
 
 1927 
 
 1928 
 
 1929 
 
 1930 
 
 1931 
 
 1932 
 
 1933 
 
 1934 
 
 1935 
 
 1936 
 
 1937 
 
 1938 
 
 1939 
 
 1940 
 
 1941 
 
 1942 
 
 1943 
 
 1944 
 
 1945 
 
 1946 
 
 1947 
 
 1948 
 
 1949 
 
 500 
 
 600 
 
 50 
 
 100 
 
 1 
 1 
 I 
 1 
 
 19,899 
 1 
 1 
 
 I 
 1 
 1 
 1 
 
 1.000 
 1,000 
 
 1,350 
 
 1.000 
 
 500 
 
 1,700 
 
 1 .075 
 
 853 
 
 8,479 
 
 10,000 
 
 82 
 
 1 
 
 C 
 
 
 70, 
 112 
 156 
 250 
 292 
 
 268 
 352, 
 271 
 202 
 
 1 
 043 
 .088 
 104 
 ,989 
 ,300 
 
 1 
 
 102 
 977 
 ,908 
 ,904 
 
 it 
 B 
 -It 
 
 1,134 
 3,790 
 960 
 1.900 
 2..500 
 3,563 
 2,500 
 3,500 
 
 5,914 
 
 11,500 
 21,000 
 7,500 
 12,000 
 10,000 
 
 T3 
 
 50 
 18 
 
 300 
 100 
 
 400 
 
 1,000 
 5,350 
 3,450 
 4,220 
 1,923 
 
 200 
 
 n 
 
 e 
 
 762 
 750 
 300 
 300 
 500 
 100 
 
 2,000 
 
 6,000 
 12,000 
 10,000 
 
 8,000 
 11.000 
 
 7,000 
 
 o 
 
 a 
 
 0) 
 
 d 
 u 
 
 n 
 
 a 
 
 <A 
 CO 
 
 20.000 
 12.500 
 31.519 
 20.584 
 21.000 
 25,000 
 17,332 
 1 
 1 
 1 
 I 
 19,613 
 
 o 
 a 
 .3 
 
 j3 
 
 O 
 .S3 
 
 3 
 I-) 
 
 S 
 09 
 CO 
 
 S3 
 
 s 
 
 CO 
 
 B 
 
 > 
 
 ^ Production not disclosed. 
 
 * Includes a small tonnage from Kings County. 
 
70 GYPSUM IN CALIFORNIA [Bull. 163 
 
 A much larger mill was built at Palmdale in 1901. Two oil-fired 
 calcining kettles had a capacity of 40 tons of stucco a day. 
 
 A eontcmpoi-ary producfM- was the Fire Pulji Plaster Company which 
 manufactured a special plaster containing stucco mixed with clay and 
 asbestos fiber. In 1904 this company opened a deposit in Charlie Canyon 
 north of Castaic. After floods washed out the access road this deposit 
 was abandoned, and operations were transferred to Palmdale. Both the 
 Alpine Plaster Company and the Fire Pulp Plaster Company w^ere 
 active in Palmdale in 1909, but by 1915 the high grade gypsum was 
 exhausted and operations were abandoned. 
 
 The third period, which lasted until 1919, covers the life of the Pacific 
 Cement Plaster Company which worked the deposits on the north side 
 of Bristol Lake near Amboy, a station on the main line of the Santa Fe 
 railroad. California's yearly production of gypsum fluctuated widely 
 but reached an average of 35,000 tons a year. The production from 
 Bristol Lake marks the first shift of the gypsum industry to the south- 
 eastern desert regions. 
 
 The Pacific Cement Plaster Company commenced operations in 1906, 
 and by 1907 a mill was in operation at Amboy. The operation consisted of 
 scraping away the thin, salty overburden, loosening the gypsum wdth 
 plows, and scraping the gypsum to chutes for loading into tram cars. 
 At first horses were used to pull the cars from the deposit to the mill 
 at Amboy, a distance of 2 miles. Cloudm'an,^" who visited the plant 
 during the winter of 1913-1914, reported that horses had been replaced by 
 a small steam locomotive. At the plant the gypsum was first crushed 
 and then washed to remove a considerable content of salt and dirt. At 
 that time output was 100 tons a da.y of hardwall plaster and "cement 
 plaster" used by southern California portland cement plants. 
 
 About 1916 the original mill at Amboy was abandoned and replaced 
 with a new plant approximatel}^ 2 miles southeast of Ambo3\ This mill 
 contained a rotary drier in which the gypsum received a preliminary 
 treatment. The drying caused the gypsum crystals to decrepitate and 
 release much of the fine silt which Avas swept out of the drier with the 
 draft. The material produced by the drier contained about 94 percent 
 gypsum. About half of the output was sold to the portland cement plants 
 at Victorville and Oro Grande for use as retarder, one-third as agricul- 
 tural gypsum, and the remainder was made into calcined products. 
 
 On September 2, 1919 the Consolidated Pacific Cement Plaster Com- 
 pany, as the operation had been known for several years, sold out to the 
 United States Gypsum Company; and the third period came to an end. 
 A number of other deposits were active during the third period and 
 contributed a significant portion of the production at that time. There 
 seems to have been two separate operations at the Mule Shoe ranch 
 property. Some gypsum was mined before 1893. but the main period of 
 production was from 1908 to 1914. J. F. Dunne operated one quarry, 
 and at least part of the output was made into plaster at Santa Cruz. 
 Dunne reported in 1915 that the quarry had been closed for some time. 
 Also from about 1900 to 1915 the Lyons Gypsum Company was shipping 
 gypsum from King City, and at least some of it came from a leased deposit 
 near the Dunne Quarries. In 1916 the Lyons Company bought the Dunne 
 
 wCloudman, H. C, et al., San Bernardino County: California Min. Bur. Rept. 15, pp. 
 S69-870, 1916. 
 
Part 2] MINING, PROCESSING, AND MARKETING 71 
 
 Quarries but there ^vas no furtlier productiuu reported. Mudi later two 
 other compauies produeed ap:ricultnral gypsum from tlie Mule Shoe 
 Ranch deposit. The Trianj^le Fertilizer Company mined a few hundred 
 tons from 1938 to 1942. and the [Monterey Gypsum Company was a pro- 
 ducer during 194-1: and 1945. 
 
 Another competitor worked the Koehn Lake deposit which was dis- 
 covered in 1909.«i A plaster mill built in 1910 was operated until 1913 
 by the Crown Plaster Company and in 1913 by the Gypsum IMining 
 Company. Apparently the deposit remained idle until 1926. Since then 
 C. A. Koehn. Jennie E. Daly, and more recently A. D. Daly have pro- 
 duced a small but regular output of agricultural gypsum. 
 
 Still another producer active during the third period was the Acme 
 Cement and Plaster Company. In 1909 this company had a calcining 
 plant in Los Angeles in wliich crude gypsum from Arizona was treated. 
 The property of the Fire Pulp Plaster Company was acquired in 1910, 
 but there was no production. They became a California producer in 1916 
 with the acquisition and development of the deposit on China Ranch, 
 Inyo County. The gypsum bed was mined with open stopes opened from 
 tunnels. For a time mining was carried on at the rate of nearly a thousand 
 tons a month, but the mine was permanently closed on October 31, 1917. 
 The fourth period began with the appearance of the United States 
 Gypsum Company among the California producers and ended about 1940 
 when gypsite production became important. 
 
 Perhaps as early as 1910 the United States Gypsum Company was 
 studying California gypsum deposits. The Midland deposit w^as selected 
 and a four-year development program was begun in 1916. As stated 
 above they bought the Amboy deposit and plant late in 1919. The United 
 States Gj'psum Company may not have operated the Amboy calcining 
 plant, for most of the output at this time was used by the portland ce- 
 ment industry. 
 
 The completion of the Santa Fe Railroad's Ripley branch in 1922 made 
 it possible to mine gypsum economically from the Midland deposits. The 
 last year for which production from Amboy was recorded was 1924. A 
 crushing and grinding plant was in operation at JMidland in 1925, the 
 output from which was largely portland cement retarder. A calcining 
 plant of 300 tons daily capacity was put into operation in August 1928. 
 By 1944 the capacity of the calcining plant had been increased to 800 
 tons per day, and a wall-board machine was in operation also. 
 
 The Fish Creek Mountains deposits likewise were known at an early 
 date, but their large scale exploitation had to await the development of 
 cheap transportation. The San Diego and Arizona Eastern railroad, com- 
 pleted in 1920, passed 25 miles south of the gypsum deposits, and soon 
 after that the Imperial Gypsum and Oil Corporation acquired large gyp- 
 sum claims in the Fish Creek Mountains. Development, which included 
 the construction of a narrow gage railroad from the San Diego and Ari- 
 zone Eastern to the deposit, was completed in 1922; and the first ship- 
 ments of crude gypsum were made in October of that year. The opening 
 of the Fish Creek IMountains deposit resulted in an increase of nearly 100 
 percent in the total gypsum production. 
 
 MHess F L Gypsum deposits near Cane Springs, Kern County, California : U. S. Geol. 
 Survey Bull. 430, p. 417, 1910. 
 
'''^ GYPSUM IN CALIFORXIA [Bull. 163 
 
 About the same time the California Gypsum Corporation staked a 
 group of claims 2 miles south of the Imperial Gypsum and Oil Company's 
 holdings. No development was done, and the claims have lapsed. 
 
 Late in 1924 the Pacific Portland Cement Company bought the Fish 
 Creek Mountains operation and built a calcining plant of 300 tons daily 
 capacity at the junction of the narrow gage railroad and the main line. 
 The plant and the dwellings of the company employees was named Plaster 
 (;ity. For about ten years the output of the Plaster City plant nearly 
 equaled that from Midland. After that the Plaster City production not 
 only fell sharply compared to the total but declined absolutely as well. 
 The Pacific Portland Cement Com])any began to withdraw from the gyp- 
 sum business after World War II. The Plaster City plant was sold to the 
 Ignited States Gypsum Company in July 1945. Gypsum properties in 
 Nevada were disposed of about the same time and a wallboard plant in 
 Redwood City in 1949. 
 
 In the fifth period the United States Gypsum Company remained the 
 dominant producer. To complete tlie story of the Fish Creek Mountains, 
 the United States Gypsum Company immediately undertook a program 
 of modernization and expansion. Since its completion a major proportion 
 of California's gypsum production has passed through Plaster City, al- 
 though the Midland operation is still producing. 
 
 The fifth period features the large scale use of agricultural g.ypsum. 
 A consumption of 3,618 tons in 1933 rose to '490,268 tons in 1947. An esti- 
 mated five-sixths of the 1947 total was gypsite mined in the San Joaquin 
 Valley. The gypsite industry is characterized by a large number of small 
 operations, most of whom have had but a short life. The Bureau of Chem- 
 istry has had almost continuous difficulty with them over failure to tag 
 shipments properly and from failure to meet guarantees.^- There are, 
 however, a few large operators wliose output over a period of several years 
 compares with that of the largest producers of high grade rock gypsum. 
 ]\Iost of the gypsite has come from near Lost Hills. No gypsite was 
 mined there until 19.30 when one company was registered. The H.M. 
 HoUoway Company's first production came in 1934. Most of the other 
 gypsite deposits operated during the fifth period were discovered and 
 worked on a small scale prior to 1920. They include deposits at McKit- 
 trick, Belridge, Tumey Gulch, and Panoche Hills. 
 
 Two other significant events occurred in the fifth period. In 1938 pro- 
 duction of synthetic gypsum was begun by the Westvaco Chemical Divi- 
 sion, Food Machinery and Chemical Corporation at Newark. This gyp- 
 sum, a byproduct of the manufacture of magnesia, has found a ready 
 market as cement retarder and for agricultural use. 
 
 In 1944 Henry Kaiser entered the California gypsum industry with the 
 purchase of the San Marcos Island gypsum deposit and the Long Beach 
 calcining plant of the Standard Gypsum Company. A second calcining 
 plant, at Redwood City, was acquired in 1949 from the Pacific Portland 
 Cement Company. Very considerable quantities of gypsum are brought 
 by ship to these plants. 
 
 Mining Methods 
 Gj^psum is a low priced commodity, the average value of which at the 
 mine is reported to be about $2.45 a ton. Probably mining costs are $1.50 
 
 «2 Scott, F. T., Unpublished paper presented at the California Fertilizer Convention, 
 November 7-9, 1949. 
 
Part 2] MIXING, pROCEs^sixc, Axn marketino 73 
 
 a ton or less; and in order to achieve tliis. larjijfe uniform deposits are 
 mined by hijrhly mechanized methods. Complete recovery is rarely 
 feasible. 
 
 liiastinjj is not required for miniiif,' gypsite. The use of modern earth- 
 movinjj: equipment is an important factor in making the working of gyp- 
 site deposits jirofitable. Most of the mines use carryall scrapers of up to 
 4-cubic yards capacity tliat dumj) into trucks by means of elevated load- 
 ing ramps. Dragline scrapers have been tried, and at one deposit a Ilaiss 
 creeper-model loader is used. Stripping is done in advance of mining 
 with the same type of equipment. The maximum ratio of overburden to 
 gypsite is 1 to 1. Exj^loration work consists of bulldozer trenches, but 
 band and power earth augers are occasionally used. 
 
 Because of the irregularity of most gypsite deposits, care must be taken 
 to avoid mining worthless material and loading some trucks with waste. 
 If the scraper is set to remove a thin layer at a time the material loaded 
 is fine enough to use without further treatment. In a few cases, however, 
 grinders or screens have been installed. 
 
 Kock gyjisum must be drilletl and blasted. ( lypsum, with a hardness of 
 2. is readily ])euetrated by both churn drills and haiinner drills. AVith 
 wagon drills from '200 to 2.11) feet per drill shift in gypsum is realized. 
 Bit wear is small. Auger drills have some application but are not used 
 in California. At Arden, Nevada, auger drills with detachable tungsten 
 carbide bits replaced jackhammers in underground mining, and a marked 
 increase in drilling rate was reported.''-* 
 
 (lypsum is more difficult to blast than the harder but more brittle rocks 
 encountered in most mining because it tends to absorb the shock without 
 shattering. A comparatively slow dynamite is often used. Xo data on 
 consumjjtion of explosive for churn drill hole blasting is available, but 
 for small open pit faces explosive consumption ranges from 0.3 to 0.65 
 pounds per ton of gj'jjsum broken. For underground mining much larger 
 • inaiitities of explosive are rerptired. 
 
 I'ndergrouud openings in gyjisum reipiire little sui)port and remain 
 open for many years. Wall rocks have a wide range in properties. The 
 Tertiary clay shales do not stand inisupported. Limestones and quartzites 
 associated with the pre-Tertiary dcp(^sits are strong aiul require no sup- 
 port. Some of the qiuii"tzite is. however, an exce(M|iiiirly liard and tough 
 rock that is most difficult to drill ami blast. 
 
 Rock gypsum deposits must be explored thoroughly before mining is 
 attempted. It is to be noted that even in the desert l)oth gypsum and value- 
 less gypsiferous rock are covered by similar gypsiferous outcrops. 
 Trenches and prospect pits may be used to explore outcrops, and prospect 
 shafts have some application. At the Quatal Canyon deposit a number 
 of prospect shafts about 3 feet square and perhaps 40 feet deep were 
 sunk through the hanging wall shale to the underlying gypsum. 
 
 Diamond drilling is customarily used to explore a deposit at depth. AX 
 bits, producing a core 1^ inches in diameter, are oft(Mi us(m1. and core 
 recovery is usually close to TOO percent. 
 
 A majority of gypsum mines in California are open cut oi»erations. The 
 raaximum overburden to gypsum ratio is about li to 1. For large deposits 
 regular benches are maintained by blasting a row of churn drill holes 
 
 ss Xordberg, Bror. Manufacture of gypsum plaster and wallboard : Rock Products, vol. 
 53, no. 1, p. 140, January 1950. 
 
74 GYPSUM IN CALIFORNIA [Bull. 163 
 
 parallel to the face. Smaller deposits are drilled with jackhammers or 
 wagon drills ; and smaller, less regular benches are developed. Flat-lying 
 deposits covered with much over-burden and steeply dipping deposits are 
 mined by underground methods. Room and pillar mining is used exten- 
 sively in the eastern part of the United States and has been used in Cali- 
 fornia both at Midland and at China Ranch. Less often shrinkage stoping 
 is applicable. When hammer drills are used they are run dry because 
 the cuttings mixed with water would cause the drill to bind. The dust 
 from dry drilling, although unpleasant, is not harmful. Gypsum dust is 
 among the least harmful of all dusts, and it has even been considered as 
 a cure for tuberculosis.*'^ The replies to questionnaires sent to members 
 of the gypsum industry in a survey conducted in ]924 indicate that the 
 number of cases of tuberculosis among gypsum works is unusually low.*"^ 
 In California, however, the dust concentration in gypsum mines and 
 plants is limited by regulations of the State Division of Industrial Safety 
 to 50 million particles per cubic foot. This compares with a limit of 20 
 million particles per cubic foot for siliceous dust. 
 
 Beneficiation 
 
 The only beneficiation commonly practiced on gypsum is sorting. Re- 
 cently, however, a washing plant has been installed in Nova Scotia to 
 clean crude gypsum before loading it on sliips for transport to plants 
 on the east coast of the United States.**** Sorting with power shovels is 
 commonly carried out in open pits during loading. In the California 
 deposits gypsum differs from anliydrite or other waste enough so tliat 
 it may be easily identified visually. More rarely hand sorting from belts 
 has been employed. In the Utah Construction Company's mill at Inea 
 Siding provision was made for hand picking of waste from the belt that 
 fed the first grinder, but this station was manned only when labor was 
 plentiful. One gypsite producer installed a screen to remove stones from 
 the gypsite. 
 
 Experimental work on the beneficiation of gj'psum has. however, been 
 carried out. Some interesting experiments have been made by the Idaho 
 Bureau of Mines and Geology.**" although it cannot be assumed that the 
 results would be duplicated Avith all gypsum. The material used was white 
 gypsum that contained bands and nodules of gray siliceous limestone but 
 no clay. It had the following mineral composition : 
 
 Percent 
 
 Gypsum 83.7 
 
 Anhydrite 4.8 
 
 Calcite 2.1 
 
 Insoluble 6.0 
 
 R=03 1.0 
 
 Others 2.4 
 
 « Forbes, J. J., Davenport, S. J., and Morgis, G. G., Review of literature on dusts : U. S. 
 
 Bur. Mines Bull. 478, pp. 238-242, 1950. 
 ^ Rock Products, Experience of gvpsum products manufacturers : Rock Products, vol. 27, 
 
 no. 13, pp. 31-33, June 29, 1924. 
 ^ Rock Products, Plant operations geared for lowered unit cost: Rock Products, vol. 53, 
 
 no. 12, p. 96, December 1950. 
 ^" Prater, L. S., Beneficiation tests on gj'psum rock from Washington County, Idaho : 
 
 Idaho Bureau of Mines and Geologj", Pamphlet 77, 6 pp., 1947. 
 
Part 2] MIXING, PROCESSING, AND MARKETING 75 
 
 In evaluating the tests the percent of acid insoluble in the various pro- 
 ducts was considered to be the most reliable indication of the results. 
 Screening tests on material crushed to minus | inch showed that the 
 optimum soparation was at 28 mosh. In the minus 28-mosli portion, Avhich 
 amounted to about 70 percent of the feed, acid insoluble was reduced 
 from about 6 percent to between 3 and 3.5 percent. When the plus 
 28-mesh portion was reground in a laboratory pebble mill selective grind- 
 ing did not take place, and tlie new minus 28-mesh material was but 
 slightly lower in acid insoluble than the plus 28-mesh pebble mill feed. 
 Tumbling with no grinding medium was tried on minus 1-inch feed, but 
 it resulted in a comparatively small amount of new minus 28-mesh ma- 
 ttn-jal ill which there was no appreciable reduction in the percent of acid 
 insoluble. 
 
 Two flotation tests were carried out. With soap flotation a concentrate 
 was made that amounted to 77.4 percent of the heads by weight, and the 
 acid insoluble was reduced from 3.6 percent to 1.2 percent. With amine 
 flotation there was no improvement. 
 
 These tests show that by both crushing and screening and by soap 
 flotation the quality of impure gypsum can be substantially improved. 
 In both cases, however, the recovery is so low that for an economical 
 operation a market would have to be found for the rejected material. 
 
 The selective flotation of sulfates is more difficult than the flotation of 
 sulfide ores. Not only has there been little occasion to attempt to apply 
 it to such a low cost material as gypsum, but there are technical problems 
 as well. The flotative properties of gypsum have, however, been investi- 
 gated ; ''^ and the results are summarized below. The flotation of gypsum 
 in the presence of other minerals was not studied. 
 
 Gypsum is readily floated with the soaps sodium oleate and sodium 
 palmitate. and flotation is improved by the addition of a frother such as 
 teri)ine(.)l, n-amyl alcohol, or n-heptyl alcohol. Gypsum is also floated with 
 the hard-water soap substitutes sodium oleyl sulfate and sodium lauryl 
 sulfate, and with these also a frother improves flotation. The fatty acids 
 are not efficient collectors. With xanthates or xanthates and metal salts 
 there is no flotation. 
 
 Using sodium oleate as a collector and terpineol as a frother the effects 
 of other reagents were studied. The flotation of gypsum under these 
 conditions is very sensitive to changes of pll and is most efficient under 
 slightly alkaline conditions. Flotation does not occur when either hydro- 
 chloric acid or sulfuric acid reduces the pll to 5.9. Additions of sodium 
 carbonate and calcium hydroxide sharply reduce flotation, while increas- 
 ing the quantity of sodium hydroxide first decreases flotation and then 
 increases it. 
 
 With many nonmetallic minerals, metal salts are added as conditioners 
 to improve flotation. With gypsum, however, metal salts either have 
 little effect or decrease flotation. Colloidal reagents are often used to 
 depress an undesirable mineral. With gypsum, gelatin and tannic acid 
 are efficient depressants; but sodium silicate is not. 
 
 •» Keck, W. E.. and Jasberg, Paul, A study of the flotative properties of &>psum : Am. 
 Inst. Min. Met. Eng. Trans, vol. 129, pp. 218-234, 1938. 
 
76 GYPSUM IN CALIFORNIA [Bull. 163 
 
 PROCEGSING 
 
 For the United States as a whole over 80 percent of the gypsum con- 
 sumed is in the form of calcined gypsum products. The tj'pical operator 
 jirepares the crude gypsum for calcining by crushing and fine grinding. 
 The comparatively small quantities of uncalcined gypsum used for port- 
 land cement retarder, as an agricultural mineral, or for fillers and dilu- 
 ents are withdrawn from the appropriate place in the flow sheets of 
 plants that primarily are preparing gypsum for calcining. In California 
 a large proportion of the total gypsum consumption is uncalcined gypsum 
 for agricultural purposes. Because an estimated five-sixths of this agri- 
 cultural gypsum is gypsite, the processing of rock gypsum in California 
 closely reflects the national practice. Nevertheless California has, or 
 recently has had, operatiojis that prepare rock gypsum for portland 
 cement retarder or for agricultural purposes only. 
 
 Little of the equipment used for processing gypsum is unique with 
 the gypsum industry. Crude rock from quarry or mine is reduced with 
 jaw crushers or gyratories, usually in circuit with screens and grizzlies. 
 Hammer mills are sometimes used as primary crushers, but they are 
 more widely used as secondarj- crushers and primary grinders. Roll 
 crushers are used in some installations. Rotary crushers, formerly popu- 
 lar, are seldom seen today. Gypsum is ground dry. Some gypsum is 
 naturally dry enough so that it can be ground without treatment, but 
 often the crushed gypsum is dried before grinding. The final grinding is 
 commonh' done with Raymond roller mills. At a few installations drying 
 and grinding are done simultaneously with Raymond kiln mills. 
 
 Agricultural Gypsum "" 
 
 Xearly half the gypsum produced in California is used as agricultural 
 gypsum. In recent years ajiproximately three quarters of the agricultural 
 gypsum has been gypsite containing about 70 percent gypsum, and the 
 remainder lias been higher grade material with a gypsum content of 90 
 percent or more. 
 
 Gypsum has been used as an agricultural mineral for mam^ j-ears, 
 and farmers sometimes still call it by its old name ' ' land plaster. ' ' Ben- 
 jamin Franklin encouraged its use by applying it on hillside pasture 
 in the shape of letters so passers-by could read his message written in 
 ridges of higher and greener grass, "This land has been plastered." 
 
 California agriculture used only a few thousand tons of gypsum an- 
 nually until about ten years ago when the tonnage began to increase 
 rapidly. During each of the past 5 years, approximately 400,000 tons 
 of agricultural gypsum have been used in this state, representing an 
 annual outlay of approximately $2,000,000 for material and application. 
 Thus gypsum has become the most important agricultural mineral in 
 Calif, irn'a. from the standpoint of tonnage and cost. The Bureau of 
 Chemistry has devoted increased attention to the labeling and claims 
 made for it to assure compliance with requirements of law for protection 
 of purchasers. 
 
 The State Department of Agriculture, Bureau of Chemistry, admin- 
 isters portions of the Agricultural Code pertaining to the labeling and 
 
 «• The 8eeti(in on agricultural gvpsum is essentiaUy a direct quotation from RoUins, R. Z., 
 Agricultural gvpsum, in Minerals useful to California agriculture: Calif. Div. Mines 
 Bull. ITjo, pp. lO.T-116. Certain parts of Mr. Rollins" article that are treated else- 
 where in this study have been condensed and rearranged. 
 
Part 2] 
 
 MINING, PROCESSING, AND MARKETING 
 
 77 
 
 sak^ of fcrtiliziii*!: materials and jicst control materials. The Bureau is 
 primarily a law ent"orc'(>ment ajjeney. It does not provide reeommenda- 
 tions with re<::ard to a«rrieultural praetices nor conduet investifrations 
 and field tests other than those incidental to its re<;ulatory duties. Ap:ri- 
 cultural research and ajrricultural advisory services are provided hy 
 the Tniversity of California Ap-ricultural Exjieriment Station, -with 
 head(piartprs at Berkeley, California. 
 
 Combined Sulphur Equivnh nf. Althou«rh agricultural fjyi)sum is 
 used for various reasons by ditferent farmers, its value is commonly 
 attributed to its combined suljihur content. Tli(> table below affords a 
 convenient comparison of poi-ceutapfcs on tliis basis. 
 
 
 Combined sulpJ 
 
 ur equivalent. 
 
 
 
 
 Combined sulphur 
 
 Gypsum percent 
 
 Combined sulphur 
 
 Gypsum |)ercent 
 
 Percent 
 
 Pounds 
 per ton 
 
 Percent 
 
 Potmds 
 per ton 
 
 100 
 
 18.02 
 17.09 
 10.70 
 
 i.^>.8;^ 
 
 14.90 
 13.90 
 13.03 
 
 372 
 354 
 335 
 317 
 
 298 
 279 
 2C1 
 
 f,5 
 
 12.10 
 
 11.17 
 
 10.24 
 
 9.31 
 
 8.3& 
 
 7.45 
 
 242 
 
 't.'l 
 
 00 -_ 
 
 223 
 
 90 
 
 5.") 
 
 50 
 
 45.. 
 
 205 
 
 8.j 
 
 180 
 
 80 
 
 108 
 
 75 
 
 40 
 
 149 
 
 70.. 
 
 
 
 
 
 Impurities. The impurities in San Joaquin Valley gypsite deposits 
 are mainly silica and other insoluble materials of no agricultural signifi- 
 cance. Most of these materials contain a small amount of calcium carbo- 
 nate, seldom exceeding 10 percent. A typical analysis is: 
 
 Percent 
 
 SOs 33.70 
 
 CaO 24.30 
 
 SiO= and ins()lnl)le 18.52 
 
 Combined water 15.53 
 
 Free water 2.88 
 
 Iron and ahiniinium oxides 1.86 
 
 VOi 1.07 
 
 MkO 0.4(5 
 
 Not determined : 1.02 
 
 Injurious amounts of boron, sodium chloride, or sodium carbonate have 
 not been found, although it is reported that some deposits of g3'psum 
 are near deposits of boron minerals. 
 
 I\riueral deposits contain traces of many elements, some present in small 
 amounts which can be determined chemically and some in traces which 
 can be detected only spectroscopically. Occasionally a registrant of agri- 
 cultural gypsum obtains a "complete analysis" of his material and pro- 
 poses to present all the findings on the label as his guarantee. In general 
 this is not acceptable because it may be misunderstood by the average user 
 and be a source of misrepresentation. Claim for the presence of SiO-, 
 ALO.i, Fe20.i, and for traces of such elements as titanium, tungsten, va- 
 nadium, nickel, and chromium, may be understood as positive claims for 
 their agricultural value. Their presence may be used erroneously to sug- 
 
78 GYPSUM IN CALIFORNIA [Bull. 163 
 
 gest a superiority of a crude gypsum over other gypsums for which such 
 claims are not made. 
 
 Some confusion is caused by use of the term gypsum to mean both the 
 pure chemical compound CaS04 -21120 and the comparatively low grade 
 gypsite commonly used for agricultural purposes. Gypsite is a variable 
 mixture of gypsum and impurities, and low grade products may contain 
 only a small percentage of actual gypsum. 
 
 Some anhydrite (CaS04) is sold as an agricultural mineral in Cali- 
 fornia, but most of the material sold liere is either gypsum containing 
 essentially gypsum 100 percent, or gypsite containing gypsum 50 percent 
 to 70 percent. All three forms appear to be of equivalent agricultural 
 value on the soil when compared on an equivalent basis. For example, 
 either 79 pounds of anhydrite or 143 pounds of gypsite containing 70 
 percent gypsum, would be equivalent to 100 pounds of pure gypsum. 
 
 The term calcium sulphate is loosely used to designate both the hy- 
 drated form, CaS04-2Ho(), and the anhydrous form, CaS04, and the 
 ambiguous term should be avoided unless used in a context where its 
 meaning is clear. Section 1025 (e) of the Agricultural Code requires the 
 anah'sis of gypsum to be stated on the tag in terms of "the percentage 
 of calcium sulphate therein." This phrase is interpreted to mean the 
 percentage of gypsum, CaS04 -21120, inasmuch as this is the actual in- 
 gredient in most such agricultural minerals. 
 
 Because 100 pounds of anhydrite may combine with 26.5 pounds of 
 water to form 126.5 pounds of gypsum, pure anhydrite is sometimes said 
 to have a gypsum equivalent of 126.5 percent. 
 
 Gypsum is defined by law as an agricultural mineral. It is not a fert- 
 ilizer and it should not be referred to as such. In the terminology of 
 the law, which is familiar to farmers in the state, the term fertilizer, or 
 more properly commercial fertilizer, refers to materials containing 5 
 percent or more of nitrogen, available phosphoric acid, or water-soluble 
 potash, collectively or singly. Commercial fertilizers and agricultural 
 minerals may serve different purposes and the two should not be con- 
 fused. Gypsum does not contain any nitrogen, phosphoric acid, or potash. 
 A reference to gypsum or any other agricultural mineral as a fertilizer 
 may be a form of misrepresentation and in violation of law. Similarly 
 the term plant food is so commonly used to mean the three primary 
 ingredients in commercial fertilizers, that generally it should not be 
 used with reference to gypsum. The term fertilizing materials is properly 
 used to refer collectively to commercial fertilizers, agricultural minerals, 
 manures, auxiliary plant chemicals and soil amendments. 
 
 Users have sometimes been misled by the ambiguous statements that 
 gypsum contains sulphur or that it contains lime. To the average 
 user, sulphur means elemental sulphur and lime means quicklime (CaO) 
 or slaked lime (Ca(0H)2) and to some it means calcium carbonate 
 (CaCOa). Gypsum does contain some chemically combined sulphur, but 
 it does not contain elemental sulphur ; neither does pure gypsum contain 
 any of these calcium compounds. The problem is further complicated by 
 the fact that gypsum, elemental sulphur, and three liming materials 
 (quicklime, hydrated lime, and limestone, which is calcium carbonate) 
 have distinctly different agricultural uses, and use of one when another 
 is more appropriate may be ineffective or detrimental. Gj^psum is not 
 a liming material. Elemental sulphur tends to make soils acid; liming 
 
Part 2] MINING, PROCESSING, AND MARKETING 79 
 
 materials tend to make soils alkaline; {rypsum has no immediate eflFoct 
 on acidity or total alkalinity of the soil, but its use may influence the 
 form of the alkalinity. The differentiation between these materials by 
 users may be somewhat confused by the fact that some mixtures of the 
 different chemicals have been sold in California. For example, mixtures 
 of calcium carbonate and gypsum have been marketed here, and a natural 
 mixture of elemental sulphur and gypsum has been brought into the 
 state for agricultural use. 
 
 Source. Much of the agricultural gypsum used in California comes 
 from the gypsite dejiosits fouiul in the western foothills of the San 
 Joaipiin Valley. Agricultural gypsum is also prepared from rock gypsum 
 by tine grinding. Most of the rock gypsum is ground b.v producers who 
 arc i)rimarily engaged in tlie plaster business. Some synthetic gypsum 
 is used for agricultui-al purpo.ses. It is of interest that approximately 
 half of nornuil superphosphate is anhydrite, and many tons of this are 
 used as a commercial fertilizer in California. 
 
 Agricultural Use. Mo.st of the agricultural gypsum sold in California 
 is used in San Joaquin Valley within trucking distance of local deposits, 
 although a portion of the tonnage is used in other parts of the state. It is 
 applied to improve soil texture, increase permeability to water, alleviate 
 severe clod and crust formation, render the soil easier to work, and to aid 
 in the reclamation of alkali soils. Gypsum reacts Avith sodium carbonate, 
 commonly called black alkali, to form sodium sulphate, commonly called 
 white alkali, and calciuju carbonate, which is the same as limestone. 
 Sodium suli)hate is much less injurious to plant life than sodium carbon- 
 ate, so the conversion is of distinct advantage. Soils alkaline with sodium 
 carbonate are sticky when wet, and set to a hard cake when dry. Addi- 
 tion of gypsum aids in flocculating the mass and tends to make the soil 
 loose and friable. 
 
 Gypsum is applied to soils where many of the diversified crops are 
 grown as in the San Joaquin Valley, and particularly on those for 
 potatoes in Kern County where most growers use gypsum primarily to 
 imjirove penetration ])y water during irrigation. Gypsum is also used 
 on sulphur-deficient soils to supply this element to alfalfa and legu- 
 minous cover crops. The use of gypsum in California is correlated with 
 soil type rather than with any specific crops, but the other crops most 
 commonly grown in the area of greatest use include citrus and deciduous 
 orchards, viiieyards, cotton, aiul vegetables. No accurate data are avail- 
 able with regard to the tonnage of gypsum used on specific crops or in 
 specific counties. 
 
 Gyj^sum is not suitable for reducing acidity of soils. However, most 
 agricultural .soils in California are commonly somewhat alkaline, and 
 acid soils are a problem in only a few places in the state. Gypsum may 
 be largely wasted if applied to acid soils or to light loam or sandy soils, 
 unless an actual deficiency of soil-sulphur or soil-calcium is involved. 
 
 Application. The rate of application of gypsum varies greatly de- 
 pending ui^on tlie crop involved, the degree of correction required by the 
 soil, and the purpose for which it is used. In general, applications range 
 from less than 1 ton to as high as 20 tons per acre. Some soils are given 
 but a single application and some are given regular annual applications 
 
80 GYPSUM IN CALIFORNIA [Bull. 163 
 
 for several consecutive years. It is possible that a soil might be more or 
 less permanently corrected by a program of annual applications over a 
 sufficient period, but this seems not to have been demonstrated. 
 
 Gypsum is usually spread on the soil and turned under by shallow 
 cultivation. It is sometimes applied to soils bj^ means of end-gate spreaders 
 attached to the same trucks that are used to haul it from the mines to 
 the fields, and several special types of equipment have been developed 
 in the San Joaquin Valley to minimize labor in spreading this agricul- 
 tural mineral. 
 
 Some application of gypsum has been made by dissolving it in irri- 
 gation water. However, only about a quarter of an ounce of gypsum 
 can be dissolved in a gallon of water under most favorable circumstances, 
 which is equivalent to about 2^ tons in one acre-foot of water. This low 
 solubility and the difficulties involved in adequately mixing the gypsum 
 with the incoming water present a problem. Mechanical arrangements 
 have been developed for metering gypsum into irrigation water at the 
 rate of several hundred pounds per acre. This method is particularly 
 useful when gypsum is being added to correct an unfavorable sodium- 
 calcium ratio in the irrigation water. 
 
 If gypsite containing gypsum 70 percent were used in such a manner, 
 the sludge comprised of the 30 percent of the more insoluble impurities 
 might clog the irrigation system. This method of application would seem 
 satisfactorily possible only when higli grade gypsum is used, and only 
 when low rates of application are desired. 
 
 Much of the gypsum is applied during the winter months when truck- 
 ing facilities are readily available, but some is applied throughout the 
 year as may be seen from the quarterly tonnage statistics published by 
 the State Bureau of Chemistry. 
 
 Soil Conservation Program. In accordance with the soil conservation 
 program, the Federal Production and jMarketing Administration makes 
 certain payments to farmers who apply soil sulphur or its equivalent as 
 combined sulphur in the form of gypsum to an existing stand of, or in 
 connection with, a full new seeding of perennial or biennial legumes, 
 perennial grasses, green manure crops in orchards, permanent pastures 
 seeded alone or with a nurse crop, and winter legumes; or where the 
 County Committee determines such application is necessarj- to correct 
 alkali soil conditions. 
 
 Information is not available to show what percentage of the gypsum 
 used in California was eligible for payments under the P. M. A. program 
 in 1949, but partial data indicate that about half the gypsum used in 
 San Joaquin Valley in 1947 was used in an eligible manner. Payment 
 is made on a basis of the amount of sulphur equivalent, and it is reported 
 that in 1947 pa^-ment was made on 210,847 tons of gypsum (18 percent 
 combined sulphur) applied to 294,690 acres on 4,452 farms. In 1946 
 payment was made on 23,751 tons of ''available sulphur" applied on 
 5,250 farms, on 219,630 acres. 
 
 Statistics of Sales. The law requires each registrant of agricultural 
 minerals to submit a quarterly statement of sales and pay a tonnage 
 license tax of 10<i5 per ton. These reports are regularly audited. The 
 private business of individual firms is safeguarded by publishing figures 
 
Part 2 
 
 MIXING, PROCESSING, AND MARKETINt; 
 
 81 
 
 only for those types of a'2:ritultiiral minerals reported by three or more 
 firms, but fjypsilm lias always been reported by a larp:e number of firms. 
 The tonnajre (»f afrrieuliural <rypsuin ^old in ralifornia during the last 
 2;") years is siiown in the table below. 
 
 In tlie same 25-year interval, the total tonnage of all agrieultural 
 minerals sold in California iiK-reased from 44,241 to 422.484 and the 
 tonnage of eommereial fertilizers increased from G6.274 to 511,460. In 
 1024. gypsum represented approximately 10 percent of the total tonnage 
 of agricultural minerals. In 1949. it represented approximately 80 
 percent. 
 
 The tonnagi' of gypsum liandled in 1!'48 may be better visualized by 
 considering that it was e(iuivalent to about 40.000 truckloads of 10 tons 
 each, or more than 100 truckloads per day everj' day in the year. Assum- 
 ing a jirobablv average liaul of 5!) miles, this represents a total haul of 
 about 2,000,000 miles. 
 
 Tons of agricultural gypsum sold in California. 
 
 Year 
 
 Tons sold 
 
 Year 
 
 Tons sold 
 
 1924 
 
 4.085 
 
 0,504 
 
 11,049 
 
 10,185 
 
 14,120 
 
 15,209 
 
 11,449 
 
 5,.583 
 
 4.410 
 
 3,018 
 
 7,914 
 
 16,787 
 
 17,328 
 
 19.37 .. 
 
 24,218 
 
 1925 
 
 1938- 
 
 17.580 
 
 1926 
 
 1939.. . 
 
 42,878 
 
 1927 
 
 1940 
 
 77,195 
 
 1928 . . 
 
 1941 .. 
 
 122,304 
 
 1929 
 
 1942. 
 
 185,856 
 
 19,30 ... 
 
 1943 
 
 300,980 
 
 1931 
 
 1944 
 
 395.174 
 
 1932 
 
 1945 
 
 367.108 
 
 1933. 
 
 1940 
 
 414.286 
 
 1934 
 
 1947 
 
 490,268 
 
 1935 
 
 1948 
 
 394,979 
 
 1936 
 
 1949.. 
 
 338,340 
 
 
 
 
 The tonnages shown represent crude gypsum as sold. The available 
 data do not permit an accurate calculation of the actual gypsum equiva- 
 lent for each year, but in recent years approximately three-quarters of 
 the tonnage has been San Joaquin gypsite containing gypsum about 70 
 percent and one-quarter has been higher grade material containing 90 
 percent or more. 
 
 Requirements of Law. Oypsum is classified by the Fertilizing Mater- 
 ials Article of the Agricultural Code as an "Agricultural Mineral." It 
 must be sold in accordance with the provisions of this law, which requires 
 among other things that : 
 
 (1) Gypsum must be from the supply of a person or firm w'ho has 
 obtained from the Bureau of Chemistry a certificate of registration for 
 agricultural minerals, and who has registered each composition to be sold. 
 
 (2) Gypsum can be sold only by the holder of a fertilizer salesman's 
 license. There are several exceptions : a registrant may sell his own regis- 
 tered products without a fertilizer salesman's license and such a license 
 is not required for a dealer to sell gypsum in a registrant's package from 
 a fixed place of business. 
 
 (3) Each lot or bag of gj^psnm must bear a tag stating the percentage 
 of gypsum (CaS04 -21120), and the name and address of the registered 
 producer. If the material is sold in a loose lot, a tag bearing the required 
 
82 GYPSUM IX CALIFORNIA [Bull. 163 
 
 information should be firmly attached to a stake driven into the pile so 
 as to be plainly visible while in transit and upon delivery to the user. 
 
 (4) A tonnage license tax of 10^ for every ton sold must be paid 
 quarterly by the registered producer. 
 
 It is a misdemeanor to make any misrepresentation in connection with 
 the sale of any fertilizing material. For example, it is not acceptable 
 to claim that gypsum "contains sulphur" or that it "contains plant 
 foods" or that it is a "fertilizer" if such claims are made in a manner 
 that may lead the purchaser to believe the material contains elemental 
 sulphur, nitrogen, phosphoric acid, or potash. 
 
 Admimsiration of Laiv. Tlie Bureau of Chemistry administers the 
 Fertilizing ]\Iaterials Article of the Agricultural Code as well as certain 
 portions of the Code pertaining to other agricultural chemicals. The main 
 office and laboratory of the Bureau are in Sacramento. Branch offices are 
 in Los Angeles, San Francisco, and Visalia. Inspectors travel throughout 
 the state. and regularly draw official samples of gypsum, as well as other 
 agricultural chemicals offered for sale in California. The oificial samples 
 are analvzed in the laboratorv and the results of analvses are sent to 
 the user of the particular lot sampled, to any dealer who may be con- 
 cerned with the particular lot, and to the registered producer. There 
 is no charge for this service. If analysis shows that there is a deficiency 
 of economic significance in the lot sampled, the registrant is requested 
 to produce evidence that proper adjustment has been made to the pur- 
 chaser. 
 
 In order to permit reasonable leeway for unavoidable variations in 
 marketing, the law provides that a lot of g^q^sum is not to be considered 
 deficient unless the percentage is low by more than 5 percent of the 
 guarantee. For example, if a lot is guaranteed to contain gypsum. 70 
 percent and contains less than 66.5 percent, it is deficient and to sell it 
 or to offer it for sale is a violation of law. 
 
 All claims made with regard to gypsum and other fertilizing materials 
 are subject to jurisdiction of the law. The Bureau examines advertise- 
 ments in periodicals, advertising distributed in the form of cards, leaflets, 
 bulletins, or letters, and also considers radio advertising, salesmen's 
 verbal claims, and all other claims made directly or indirectly in connec- 
 tion with the sale of these agricultural chemicals. Prompt action is taken 
 against misrepresentation in any form in order that farmers in California 
 may purchase agricultural chemicals with confidence and satisfaction. 
 
 Criminal complaints are filed wlien necessary to secure compliance with 
 law. Repeated violations by firms dealing in g}q)sum have resulted in 
 cancellation of certificates of registration, without which any sale is a 
 misdemeanor. Constant vigilance and thorough enforcement of law not 
 only discourages violations and secures some compensation of purchasers 
 for economic cheats in the materials they buy but, by its presence alone, 
 a well-administered law serves to minimize attempts of fraud and mis- 
 representation. 
 
 Sampling. Much of the gypsum used in California is hauled loose in 
 truckload lots directly from the mine to the field on which it is to be used, 
 so it remains in the channels of trade and subject to inspection and sam- 
 pling for a shorter time than other agricultural chemicals.Inspectors must 
 arrange their sampling acti\aties according to availability of the mate- 
 
Part 2] MINING, PROCESSING, AND MARKETING 83 
 
 rial lor inspection. Saniplos are usually (Ira^n from truekloads en route 
 and oecasionally from lots deliviM-cd and left intaet at farms. Some {gyp- 
 sum is sold in ha^^s, and this material is subject to iiisjiection and sampling; 
 wherever found in hands of dealers or purchasers. 
 
 Section 1();{7 of the Ajrricidtural Code provides that if the fertili/.iufr 
 material is packaj^ed in containers of less than 10 pounds, one package 
 of the material may be taken as a sample to represent the lot of which 
 it is a part, but gypsum is seldom sold in small jiackages. 
 
 When gypsum is packaged in containers of 10 pouiuls or more, each 
 official sample consists of at least 1 pound of material taken in the follow- 
 ing manner : A sampler is used to remove a core diagonally from end to 
 end of the bag. Cores are taken from all bags if 20 or fewer are present. 
 If 21 to 200 bags are present, 20 cores are taken from as many bags. If 
 more than 200 bags are present, cores are taken from 20 bags plus 1 bag 
 for each additional ton in excess of 10 tons. The portions are thoroughly 
 mixed on a clean rubber sheet, oil cloth, or paper, and reduced by quarter- 
 ing to the ([uantity of sample required. Opposite quarters are placed in 
 one sample container and tiie remainder in anotlier for a duplicate sample. 
 
 When gypsum is sold in a loose lot by truckload or carload, the load 
 constitutes one package. An official sample is taken in the following man- 
 ner : The outer surface is scraped aside before inserting sampler, because 
 the load may have been wet with a hose to reduce dust or the wind may 
 have blown the fine material from the surface, and at least 20 approxi- 
 mately equal cores are taken from fairly evenly distributed parts of the 
 quantity. If more than 10 tons are contained in a lot, two cores are taken 
 for each additional ton. Portions are taken with a trowel when the mate- 
 rial contains large lumps or when for other reason it is not possible to use 
 a sampler. Lumps are broken if necessary and the material is mixed, 
 quartered, and placed in sample containers. 
 
 An official sample of a fertilizing material is sealed before removal 
 from premises where it was drawn. The seal bears the date ; name of prod- 
 uct as given on the label, if any ; signature of per.son acknowledging the 
 sample; inspector's initials and sample number. The duplicate portion is 
 scaled and left with the party whose stock was sampled or left on the 
 premises where it was draw^n. 
 
 A total of 180 official samples of gypsum were drawn and analyzed 
 during 104S ; these represented a total of 10,256 tons. Since 304,979 tons 
 of gypsum were sold in California during 1948, it can be seen that 2.6 per- 
 cent of the total tonnage was specifically examined by the Bureau of 
 Chemistry. For every sample of gypsum drawn and analyzed during the 
 year, approximately 2,194 tons were sold. By way of comparison, one 
 sample of commercial fertilizer was drawn for every 262 tons sold. In 
 general, commercial fertilizers are more expensive and more important 
 to farmers than agricultural minerals, and the purpose of the law is served 
 most effectively and economically by sampling the more important mate- 
 rials more intensively. 
 
 Analyses for Users. The law provides that a per.son who is actually 
 using or intends to use an agricultural mineral for fertilizing purposes 
 may submit a sample for analysis to determine conformity or noncon- 
 formity of the material to the guarantee under which it is sold or is to 
 be sold. The user submits information with regard to the lot of material, 
 a copy of the tag, and the service fee which is $4 for analysis of gypsum. 
 
84 GYPSUM IN CALIFORNIA [BuU. 163 
 
 Users rarely submit samples for analysis because a report issued on such 
 a sample does not have the legal status of a report issued on an official 
 sample drawn directly by the Bureau, and no charge is made for official 
 samples. 
 
 riihlications. The results of analyses of official samples of commercial 
 fertilizers and agricultural minerals drawn during each calendar year 
 are published annually by the Bureau. These analj'ses serve not only as 
 a guide in administration of the law, but are an important source of infor- 
 mation to users. Farmers can readily compare analyses of different types 
 of materials, and compare the records of different registrants in meeting 
 the guarantees made for their materials. Interested persons familiarize 
 themselves with the law governing sales of gypsum to assure value re- 
 ceived for the money they spend when buying their supplies. 
 
 Copies of the law, annual reports of this Bureau, lists of registered 
 firms and of registered products, special publications providing analyses 
 of official samples, announcements with regard to special items of inter- 
 est, and other informative publications of agricultural chemicals are avail- 
 able upon request from the Bureau of Chemistry, 1125 Tenth Street, 
 Sacramento 14, California. 
 
 Portland Cement Retarder 
 
 The Portland cement industry is an important consumer of uncalcined 
 gypsum, and in California 100,000 to 150,000 tons of gypsum a year are 
 used by cement plants. The gypsum, which serves to retard the naturally 
 fast set of Portland cement, is added to the clinker before grinding. 
 Specifications limit most cements to 2 percent SO.3, although some cements 
 may contain up to 2h percent SO-.. These percentages are achieved by 
 the addition of 85 to 100 pounds of gypsum per ton of clinker. Greater 
 quantities reduce the final strength of cement. The function of gypsum 
 in the setting of portland cement is a complex matter that is not com- 
 pletely understood. Bouge has summarized the work of many investi- 
 gators."^^ 
 
 Portland cement plants commonly require that the gypsum contain 
 a minimum of 92 to 93 percent CaS04 -21100, although material contain- 
 ing 85 percent gypsum or less has been used. Gypsum of over 90 percent 
 purity is not likely to contain harmful quantities of deleterious sub- 
 stances. Anhydrite, however, cannot be indiscriminately substituted for 
 gypsum on an equivalent SO3 basis. The use of anhydrite as portland 
 cement retarder is discussed more fully in another section of this report. 
 
 Portland cement plants require sized gypsum. Probably a majority are 
 accustomed to using and require "pebble" gypsum which is plus f inch 
 and minus 1-| inches. These plants find that fine gypsum is difficult to 
 handle and store, and also that better grinding is accomplished when 
 the gypsum and clinker are approximately the same size. The upper size 
 is usually limited by the capacity of the tube mills that grind the mixture 
 of gypsum and clinker, but some plants have crushers for reducing 
 coarse gypsum to a convenient size. Other plants use fine gypsum and 
 require that the gypsum be fijiely ground. A few plants that use fine 
 gypsum have grinding equipment and accept either coarse or fine gypsum. 
 
 '0 Bouse, R. H., The chemistry of portland cement, pp. 472-487. New York, Reinhold Pub- 
 lishing Corp., 1947. 
 
Part 2] MINING, PROCESSING, AND MARKETING 85 
 
 Calcination of Gypsum 
 Calcium Sulfate and Its Hydrates 
 
 It has been known since ancient times that when j^ypsuni is calcined 
 at a moderate temi>erature, the resultinjr material sets or hardens when 
 mixed with water. A thorough study of tlie system C'aSO.i-IIofJ has been 
 made by Kelley, South.ard, and Anderson.'' l\i(Ulell '- has prepared a 
 summary of this higldy technical woik lo wliich lie has added some data 
 of his own. 
 
 Althoujrh many forms of calcium sulfate anil its hydrates have been 
 |)ostulated, only six forms have been accepted or are reproducibh' in the 
 laboratory. The dihydrate (CaS04-2Ili>0) occurs naturally as gypsum 
 or may prc])ared in the laboratory by precipitation from solution at room 
 temperature or by allowing calcined gypsum to rchydrate. X-ray studies 
 show tlmt all the natural and synthetic types of gypsum have the same 
 crystal .structure and that the water of cry.stallization cannot be removed 
 witliout destroying the crystal lattice. 
 
 There are two forms of' the hemihydrate (CaS()4- HIuO). The crystal 
 structure of both is such that the water of crystallization can be varied 
 considerably without destroying the crystal structure. The more stable 
 form, alpha raS0|-UT.O may be prepared by crystallization from acid 
 solutions, dehydration of gypsum in Avater at over 97"^ C. or dissociation 
 of gypsum in an atmosphere of saturated steam. The less stable beta 
 CaS04 4Il20 differs from alpha CaS04-iH20 in energy content and 
 solubility. It slowly changes to the stable form. Beta CaS04-^H20 is 
 prepared by partly dehydrating gypsum in a vacuum at 100° C. or in 
 an atmosphere not saturated with steam. 
 
 There are three forms of anhydrous calcium sulfate. Two forms, analo- 
 gous to the hemihydrates, rehydrate in water and are called soluble anhy- 
 drite. The third form, insoluble anhydrite, does not rehydrate at an ap- 
 preciable rate. 
 
 Alpha soluble anhydrite is prepared by dehydrating alpha hemihy- 
 drate in a vacuum or at 110° C. in air saturated with w'ater vapor. Beta 
 soluble anhydrite is prepared by dehydrating beta hemihydrate at 100° C. 
 or gypsum at less than 200° C. in an atmosphere not saturated with steam. 
 The soluble anhydrites have great affinity for water and have some ap- 
 plication as drying agents. It is difficult to remove the last traces of the 
 water of crystallization without destroying the crystal structure. 
 
 Insoluble anhydrite is prepared by crystallization from salt solutions 
 at 100° C. or by heating any of the other forms of calcium sulfate for one 
 hour at a temperature up to 900° C, the dissociation temperature of cal- 
 cium sulfate. Material formed in either of these ways is identical with 
 natural anhydrite. 
 
 Sleftirtg of Gypsum Vlastcr?^ Two theories have been advanced to ex- 
 plain the setting of gypsum plaster, the crj'stallization theory and the 
 colloid hypothesis. The crystallization theory supposed that when water 
 is added, the hemihydrate goes into solution. Because CaS04 -21120 is 
 
 " Kelley, K. K., Southard, J. C, and Ander-tjon, C. T., Thermodynamic properties of 
 gypsum and its dehydration products : U. S. Bur. Mines Tech. Paper G25, 73 pp., 1941. 
 
 " Riddell, W. C, Physical properties of calcined gypsum: Rock Products, vol. 53, no. 5, 
 pp. 68-71, 102, May 1950. 
 
 " Bouge, R. H., The chemistry of portland cement, pp. 352-367, New York, Reinhold Pub- 
 lishing Corp., 1947. 
 
86 GYPSUM IN CALIFORNIA [BuU. 163 
 
 less soluble than the hemihydrate, the solution is supersaturated with 
 respect to CaSO^ -21120, and CaS04 -21:120 precipitates. 
 
 According to the colloid hypothesis, when water is added to the plaster 
 a gel is first formed. The gel slowly takes up water and changes to needle- 
 shaped crystals of CaS04 -21120. 
 
 Commercial Calcination 
 
 In the laboratory gypsum may be calcined to the hemihydrate at temp- 
 eratures as low as 130° F. Because the time to reach equilibrium at 
 such low temperatures amounts to many days, commercial calcination 
 is carried out at temperatures between 300° F. and 400° F. 
 
 Gypsum is commonly calcined in batch machines called kettles whose 
 eapacit}'- ranges from 10 to 20 tons of uncaleined gypsum. The modern 
 kettle is a steel cylindrical shell 6 to 14 feet deep and 8 to 15 feet in 
 diameter. The bottom, which is convex upward, rests directly on the 
 firebox. Rabble arms driven by a vertical shaft are placed close to the 
 bottom to prevent sticking of the charge to the hot bottom. Furnace 
 gases from the firebox pass through an annular space between the kettle 
 shell and the outside brickwork and are directed by means of baffles 
 through horizontal flues, usually four, that pass through the kettle. The 
 kettle is loaded from the top and discharged through a spout in the 
 bottom. Steam produced during calcination is vented through a dust 
 separator to the atmosphere. 
 
 The kettle is loaded with gypsum ground to 70 to 90 percent minus 
 100 mesh. Present practice is to fill the kettle as rapidly as possible ; the 
 average time is about 15 minutes. Although heat is applied at a constant 
 rate, the temperature of the charge rises rapidly to between 250° and 
 255° F. and then remains nearly constant for much of the period of 
 calcination. During this period of constant temperature, the rapid evo- 
 lution of the water of crystallization as steam causes a vigorous boiling 
 and rising of the charge. As the composition of the material approaches 
 CaS04 -11120 the boiling dies down, the charge settles in the kettle, and 
 the temperature rises again at an increasing rate. At 300° F. the material 
 has a water content somewhat less than that of the hemihydrate. Calcina- 
 tion is ordinarily stopped at about 340° F. by opening the discharge 
 spout and dumping the contents of the kettle into an adjacent chamber 
 called the hotpit. The kettle is then loaded again with raw gypsum and 
 the cycle is repeated. The time of calcination, which depends on the rate 
 of firing, is between 2 and 2|- hours. Material made in this way is called 
 single boil or first settle stucco "^ and is the semi-finished material from 
 which almost all calcined gypsum products are made. 
 
 Single boil kettle stucco approaches the composition of the hemihydrate 
 (6.2 percent H'20), but the water content ranges from the theoretical 
 down to as little as four percent. Measurements made on stucco from 
 different plants show that single boil stucco may contain as much as 
 10 percent l)eta soluble anhydrite and that as much as a third of the 
 hemihydrate may be in the beta form.'''' The relative proportions of 
 these dehydration i^roducts depend on the character of the raw gypsum, 
 
 ''* The term "stucco" is commonly useil to designate calcined gypsum that has received 
 no further treatment. Stucco is defined by the American Society for Testing Mate- 
 rials, however, as follows : "A material used in a plastic state, which can be troweled, 
 to form a hard covering for the exterior walls or other exterior surfaces of any 
 building or structure." AiS.T.M. designation : Cll-48. 
 
 ''Kelley, K. K., Southard, J. C, and Anderson, C. T., Thermodynamic properties of 
 gypsum and its dehydration products: U. S. Bur. Mines Tech. Paper 625, pp. 63-68, 
 1941. 
 
Part 2] MINING, PROCESSING, AND MARKETING 87 
 
 the conditions under which calcination was carried out. and the treatment 
 of the stucco after calcination. These proportions in turn influence the 
 properties of the stucco. The setting; time of sinprle boil stucco ranges from 
 less than 15 minutes to more Ihan 40 minutes and averages about 30 
 minutes. The tensile strength is up to about 300 pounds per square inch. 
 Like Portland cement the strength of set plaster continues to increase 
 for many hours after the initial set. The compressive strength is about 
 10 times the tensile strength. For most testing purposes tensile strength 
 rather than compressive strength is measured. 
 
 Rclalious Bctivccn the Properties of Stucco. Consistency is a mea.sure 
 of the ability of stucco to absorb water. Normal consistency is defined by 
 the American Society for Testing Materials and is determined with the 
 Vicat needle. 
 
 Normal consistency is measured by tlie weight of mixing water re- 
 quired expressed as a percentage of the dry material. 
 
 Usually a plaster of high consistency is more plastic than a plaster 
 of low consistency, but the relation between consistency and plasticity 
 is not proportional. A plaster of hieh consistency has great bulk when 
 wet and can cover a larger area than a low consistency plaster. When 
 dry, however, it is porous and less strong than a low consistency plaster. 
 
 Factors that Influence the Properties of Stucco. Most of the insoluble 
 impurities likely to be found in the raw gypsum accelerate the setting 
 time of the stucco made from it. Deliquescent salts increase the strength. 
 Increased fineness of grind of the feed accelerates the setting time, in- 
 creases the consistency, and decreases the strength. 
 
 The maximum temperature reached during calcination influences the 
 setting time. Stucco with the fastest set is made by calcining at between 
 320° and 360^ F. Maximum temperatures both higher and lower than 
 this produce stucco with a slower set. Increased strength results both 
 from increasing the time of calcination and raising the maximum temp- 
 erature. Faster calcination produces stucco of higher consistency. If the 
 calcination is carried out .so that either raw gypsum or dead burned 
 gypsum gets into the stucco, the .set is accelerated. 
 
 The effect of leaving the stucco in the hotpit is to allow calcination to 
 continue. The setting time is accelerated, the consistency is lowered, and 
 the strength is increased. Aging is the slow rehydration of the stucco. 
 Consistency is decreased, strength is increased, and the setting time is 
 retarded. Aging is desirable for casting and similar plasters. Artificial 
 aging is accomplished by adding a salt, particularly calcium chloride, 
 to the kettle charge or by .spraying a fine mist of water into a mixer 
 of stucco. 
 
 Regrinding the stucco increa.ses the consistency. Tube mills are more 
 effective than other grinders for this purpose. 
 
 Douhle Boil Kettle Stucco. Less double boil stucco is made today than 
 formerly. If the single boil stucco is retained in the kettle instead of 
 being dumped at about 340° F. the temperature continues to rise to 
 about 370 F. and then remains nearly constant. A second boiling takes 
 place, and after it subsides and the charge settles for the second time 
 there is a renewed increase in the temperature. The calcination is stopped 
 at about 415° F. because a higher temperature produces a large propor- 
 tion of dead burned gypsum or insoluble anhydrite. 
 
88 GYPSUM IN CALIFORNIA [BuU. 163 
 
 Double boil stucco is essentially soluble anhydrite. It is a material of 
 low consistency, quick set, and hi<i:h strength that was formerly used 
 for easting plaster. Most casting plaster is now made, however, by arti- 
 ficially aging single boil stucco. 
 
 The Calcination of Gypsite. In the past gypsite has been calcined in 
 kettles in California and elsewhere in the United States."^ Because of 
 gypsite 's wide variation in gypsum content, high moisture content, and 
 sometimes the presence of organic matter, the calcination is difficult. 
 Loading is done slowly in order to prevent the charge from sticking to 
 the bottom of the kettle. After each increment the charge is allowed to 
 reach the boiling stage before the next addition. The calcination time 
 for a 10-ton charge is from 3 to 8 hours. 
 
 Gypsite stucco is dark colored and slow setting. It has been used for 
 wall plaster. 
 
 Continuous Calcination. A few plants in the ITnited States calcine 
 gypsum in rotary kilns, but there are no rotary calciners in California. 
 A coarse feed from which the fines have been screened is used. 
 
 Stucco for some purposes can be prepared by flash calcination. Two 
 California plants use the Kaymond Imp kiln mill. Although it is widely 
 used for drying clay and chemicals, the Imp kiln mill has been adapted 
 for calcining at only a few plants. 
 
 The Imp kiln mill consists of a hammer mill with an exhaust fan at 
 one end of the shaft. Tlie hot gases from an adjacent furnace enter at 
 the other end. Gypsum crushed to 1 inch or finer is introduced from a 
 hopper with a star feeder into the intake stream. In a conical chamber 
 between the fan and the hammers are the whizzer blades set so as to 
 throw uncalcined lumps back towards the hammers. During the estimated 
 15 seconds the gypsum stays within the mill, flash calcination and grind- 
 ing take place simultaneously. Tlie action of the mill can be controlled 
 by adjusting the rate of feed, the temperature of the furnace gases, and 
 the position of the whizzer. The maximum capacity of the Imp kiln mill 
 is 2 to 3 tons of stucco per hour. Larger Imp mills are used as driers, but 
 gypsum has not been economically calcined in them. 
 
 The hot. finely ground stucco is removed from the furnace gases and 
 steam with a cyclone separator and cooled in air before being placed in 
 storage bins. 
 
 Stucco produced in the Imp kiln mill differs from kettle stucco in a num- 
 ber of its pliysical properties, including the time of setting and solubility. 
 Solubility tests made by W. C. Riddell '''^ show that Imp kiln mill 
 stucco contains a large proportion of the metastable hemihydrate beta 
 CaS04-^HoO. The average setting time of 15 minutes contrasts with 
 the 30-minute setting time of kettle stucco which is high in alpha 
 CaS04-in20. The rapid setting time of stucco produced in the Imp kiln 
 mill is one reason why it may be advantageously used for wallboard. 
 
 Finishing the Plaster 
 
 Stucco from the calcining kettle is ordinaril}" left in the hotpit for no 
 longer than about an hour. Continued hotpit storage allows calcination 
 to continue and usuall}" results in inferior plaster. Stucco is a very light, 
 
 '8 Turner, A. M., The manufacture of gypsum plaster — Part I: Rock Products, vol. 33, 
 _ no. 22, pp. 49-51, 1930. 
 
 " Riddle, W. C, Physical properties of calcined gypsum: Rock Products, vol. 53, no. 5, 
 pp. 70, 71, May 1950. 
 
Part 2] MINING, PROCESSING, AND MARKETIMi 89 
 
 powdory material that tends to flow like water and leaks readily through 
 small holes. Generally it is liandleil with si-rew conveyors. 
 
 Stucco is usually reground after its removal from the hotpit, although 
 stucco for certain uses is not reground by all manufacturers. It has been 
 established that grinding with steel balls increases the consistency of 
 the plaster, and stucco for hardwall plaster is usually reground in tube 
 mills. Buhr mills are used when it is not desired to increase the 
 consistency'. 
 
 The final operation is the addition of materials to regulate tlie setting 
 time, fiber, aggregate, or sometimes other additives. The additions are 
 made in batch mixers of about 1 ton cajiacity. The finished plaster is 
 l)acked in paper bags that hold 100 pounds. 
 
 The set of most plasters is modified by tlic adilition of retarders or 
 accelerators. Clay and most organic materials are retarders. Glue, starch, 
 or sugar, are effective ; but the material ordinarily used is commercial 
 retarder prepared especially for the plaster industry. Commercial re- 
 tarder is made from hoof meal, slaughter house tankage, or similar mate- 
 rial cooked Avitli lime and caustic. To obtain a setting time of 6 hours, 
 from 3 to 15 pounds of retarder per ton of plaster are required. The 
 effect of commercial retarder depends to a notable degree on the temp- 
 erature at which the plaster is to be used. Less of it is required in summer 
 than in winter. Other variables affecting the amount of retarder required 
 are tlie setting time of the stucco from which the plaster is made and 
 the presence of set-influencing impurities in the water and aggregate to 
 be mixed with the plaster. For example, the same plaster mixed with 
 different sand may have vastly different setting times. In one series of 
 tests the setting times ranged from less than 2 hours to 15 hours."^^ Con- 
 sequently the amount of retarder added depends on where and in what 
 season the plaster is to be used. Although the set can be adjusted at the 
 time of use. it is better practice to use plaster prepared by the manufac- 
 turer for the particular locality. 
 
 Most metal salts are accelerators. Gypsum, set plaster, dead-burned 
 gypsum, and anhydrite are very effective under certain conditions. An 
 addition of 10 pounds of dry gypsum per ton of plaster reduces the set 
 to 5 minutes or less, but if the gypsum is damp or the plaster is hot, much 
 larger quantities are required. Large additions of gypsum weaken the 
 I)la.ster. Salt is as effective as gypsum and may be added to hot plaster. 
 Potassium sulfate, zinc sulfate, and alum may cause efflorescence on the 
 surface of the set plaster. 
 
 Other additives may be a binder such as hair or sisal fiber, an aggregate, 
 or pigments for making colored plaster. Aggregates include sand, wood 
 fiber, vermiculite, and perlite. Usually sand is added to plaster at the 
 place of use, but some sanded plaster is prepared by the manufacturer 
 for use in areas where good plaster sand is scarce. 
 
 Anhydrous Plasters 
 
 There are a number of low consistency, high strength plasters made 
 by calcining gypsum at a temperature high enough to drive off all the 
 water of hydration. In one group of plasters the gypsum is heated to 
 about 1.000 degrees F., and to the ground calcined product accelerators 
 are added. This group includes Keene's cement, Parian cement. Mack's 
 
 ™ McAnaUy, S. G., Gypsum and gypsum products manufacture — Part VIII : Rock Prod- 
 ucts, vol. 34, no. 6, p. 58, March 14, 1931. 
 
90 GYPSUM IN CALIFORNIA [Bull. 163 
 
 cement, Martin's cement, and Magaud's cement. They differ chiefly in 
 the accelerators used. Another anhydrous plaster is flooring plaster, made 
 by calcining gypsum at a temperature high enough to decompose part 
 of the calcium sulfate. Of all the anhydrous plasters, Keene's cement is 
 the only one that is used in the United States. 
 
 Keene's Cement. Keene's cement is a gypsum product that is not 
 made in the- calcining kettle. Kaw gypsum is converted to insoluble 
 anhydrite by calcination at 600^ to 1300^ F. in beehive or rotary kilns. 
 The calcined gypsum is then finely ground. Accelerators are added that 
 cause the cement to set in 1 to 4 hours. Dehydrated alum, sodium sulfate, 
 potassium sulfate, and borax are among the accelerators used, and addi- 
 tions of about one percent are made. Keene's cement is harder and 
 stronger than ordinary gypsum plaster. The minimum permissible tensile 
 strength is 400 pounds per square iuch."'-^ 
 
 Gypsum of over 99 percent purity is required because small quantities 
 of impurities either cause discoloration or weaken the cement. Keene's 
 cement is manufactured at only tw^o or three plants in the United States. 
 Most of it is used for finishing plaster. 
 
 MARKETING 
 
 Gypsum Products 
 Building Plasters 
 
 Most of the gypsum plasters are consumed by the building industry. 
 Gypsum plaster is eminently suited for building use not only because 
 of its strength and permanence but also because of its resistance to fire. 
 In a manner analagous to the melting of ice, the temperature of set 
 plaster cannot rise above 200"' to 250^ F. until it has been completely 
 calcined. Calcination progresses through a plaster wall at the slow rate 
 of about :j-inch in 15 minutes. Exhaustive studies have established stand- 
 ards for fire resistance for numerous types of construction. For example, 
 walls having half an inch of plaster have fire resistive ratings of 45 
 minutes to 1 hour, depending on the kind and amount of aggregate in 
 the plaster and the type of lath. 
 
 The use of gypsum in building is covered by rigid specifications. 
 Specifications of the American Society for Testing Materials are con- 
 cerned with the properties of gypsum plasters and manufactured prod- 
 ucts, aggregates, and methods of testing. The American Standards As- 
 sociation has established the manner in which gypsum as well as other 
 kinds of building materials are to be used. 
 
 Basecoat plasters, of which there are four standard types, consume 
 the greatest quantity of gypsum used for building plaster. Hardwall 
 plaster, called cement plaster in other parts of the country, is the most 
 important basecoat plaster. It is applied directh^ to all kinds of lath and 
 most other surfaces except monolithic concrete. It is furnished neat which 
 means that it contains retardcr but no aggregate. When it is mixed with 
 3 parts of sand the minimum time of setting is 2 hours, and the minimum 
 tensile strength when mixed with 2 parts of sand is 125 pounds per square 
 inch.^^ Neat hardwall plaster may contain hair or sisal fiber. Although 
 
 ™ A.S.T.M. designation : C 61-40. 
 80 A.S.T.M. designation : C 28-40. 
 
Part 2] MINING, PROCESSING, AND MARKETING 91 
 
 tlie fiber does not coutriliutc to t he strnij^rtti of the i)laster. it does i)reveiit 
 excessive loss of plaster tlirou<rh the keys of some kinds of lath. 
 
 Ilardwall i)laster is mixed with as mueh as three parts by Meinfht of 
 sand at the place of use. (Jreater fpiantities of sand cause a marked de- 
 (•rease in tlie sti;enp:tli and hardness of the set plaster and reduces its 
 fire resistance. Vermicnlite and perlite may be substituted for sand pro- 
 vided that the particle size conforms to specifications for plaster sand. 
 Two to three cubic feet of vermicnlite per 100 pounds of neat plaster 
 ;ire used. P>oth vermicidite and i)erlite increase the fire resistance of 
 plaster, but the strenjith is less than when sand is used. Perlite i)laster 
 is stronjrer than that which contains vermiculite. 
 
 The second type of basecoat plaster is sanded prypsum plaster. Intended 
 for the same uses as hardwall ])laster, it is mixed with sand at the plaster 
 factory and is available both with or without fiber. Sanded gypsum 
 plaster is used where g:ood plaster is scarce or when it is desired to 
 eliminate the possibility of mixinor too much sand or inferior sand with 
 the i)lastor. 
 
 Gypsum wood fiber ]:)laster is the third type. "Wood fiber is added at the 
 plant as a substitute for sand or other aggregate. Wood fiber plaster is 
 stronger and harder than hardwall plaster and has somewhat greater 
 resistance to fire. 
 
 The fourth type is bond plaster, a material for direct application to 
 concrete surfaces. Hardwall plaster is unsatisfactory because of the 
 difference in thermal expansion between concrete and gypsum and be- 
 cause of the smooth dense surface of concrete, especially monolithic 
 concrete. Bond plaster is especially prepared to overcome these limita- 
 tions, and it is for use on concrete only. 
 
 Finish coat plasters are used for the final 3^ inch to ^ inch of the 
 plaster. The most commonly used is lime-gauging or white coat finish, 
 which is composed of three parts by volume of lime putty gauged ^^ with 
 one part of gauging plaster. Gauging plaster is a coarsely ground plaster 
 of low consi.stency and comparatively fast set. Molding plaster, used for 
 gauging lime putty for cornice moldings, resembles gauging plaster ex- 
 cept that it is ground to a fineness of 00 percent minus 100 mesh. The 
 setting time is 20 to 40 minutes, and the minimum tensile strength is 
 200 pounds per square inch.'*^ Neat hardwall plaster is unsatisfactory 
 for gauging. Keene's cement may be used neat for finishing, or it may 
 be used for gauging lime putty. Tiime-Keene's cement finishes are harder 
 and stronger than lime-gauging finishes. There are also prepared gypsum 
 finishes that require only the addition of water at the place of use. They 
 are harder than finishes containing lime ; and unlike the lime finishes, 
 U\oy may be painted as soon as they are dry. The minimum tensile 
 strength is 200 pounds per sc^uare inch, and the setting time is 20 to 40 
 minutes.^^ 
 
 Acoustical plaster is a sound-absorbing finishing plaster for use on 
 ceilings or walls in place of the usual finishing coat. It is prepared at 
 the plant and requires only the addition of water at the time of use. Al- 
 though it is hard and incombustible, acoustical plaster has a cellular 
 structure that absorbs sound. 
 
 ^ Gauging is the mixing of plaster with lime putty In order to acquire the proper setting 
 
 time and initial strength. 
 82 A.S.T.M. designation : C 59-40. 
 » A.S.T.M. designation : C 28-40. 
 
92 GYPSUM IN CALIFORNIA [Bull. 163 
 
 Prefabricated Products 
 
 A little more than half of the jrypsum consumed by the building in- 
 dustry is in the form of prefabricated products. By far the most im- 
 portant are gypsum Avallboard, lath, and sheathing board. Cast shapes 
 of several sizes are available, but they constitute less than 1 percent of 
 the total production of prefabricated gypsum products. 
 
 Gypsum board products consist of a plaster core between two layers 
 of paper. The core is made of stucco of less exacting specifications than 
 tliat required for most other plaster products. Gypsum containing 85 
 percent CaS04- 21120 is commonly used, and material of 80 percent or 
 slightly lower grade has been used satisfactorily. Two plants in Cali- 
 fornia make stucco for board products by flash calcination. 
 
 Board products are made by continuous methods on automatic ma- 
 chines that can be adjusted to make any of the standard products. Equip- 
 ment manufactured by the J.C. Ehrsam and Sons Manufacturing Com- 
 pany is very commonly used. Almost all plants use very similar machines 
 modified to their own specifications. 
 
 Wallboard is made as a single continuous strip, but when making the 
 narrower lath the machine forms three parallel strips. The special papers 
 that form the outer layers of the strips are drawn from stock rolls at 
 the head the machine. Stucco for the core is usually brought in a screw 
 conveyor to a platform over the head of the machine where carefully 
 measured amounts of additives are fed iutrrthe conveyor and mixed with 
 the stucco. 
 
 The additives usually include an accelerator. One California plant uses 
 ground set plaster, another salt water, and a third ground gypsum and 
 potassium sulfate. An important additive is starch or corn flour to pro- 
 mote the sticking of the plaster to the paper. These materials coat the 
 fine gypsum crystals that penetrate the paper and prevent them from 
 calcining during drying. Wood flour, or less commonly chopped paper, 
 is added for a filler. Increased porosity is provided by the addition of 
 soap or other means for entraining air into the wet plaster. The dry 
 ingredients are mixed with water in an Ehrsam type pin mixer. Practice 
 varies, but one California wallboard manufacturer who is no longer active 
 stated that the requirements for 1000 square feet of ^-inch board were: 
 
 Stucco 1500 pounds 
 
 Water 250 pounds 
 
 Wood flour 100 pounds 
 
 Starch 10 pounds 
 
 Soap 2 pounds 
 
 The slurry of wet plaster is placed on the moving bottom paper, and the 
 top paper is fed on immediately ahead of the forming rolls that fold over 
 the projecting edges of the bottom paper and seal them to the top paper 
 with an adhesive. When wallboard and sheathing board are made, the 
 bottom paper is scored with carborundum wheels in order that the folded 
 edges will be shaped correctly; but for lath, which has rounded edges, 
 the bottom paper is not scored. 
 
 The green board, which moves at a constant speed, is supported on a 
 moving belt, until it has partly set. For the remainder of the length of 
 the machine it moves on rollers, every third one of which is belt-driven. 
 Guides are provided at intervals to keep the board in position. Near the 
 end of the machine is the reciprocating Ehrsam punch that moves hori- 
 
Part 2] MINING, PROCESSING, AND MARKETING 93 
 
 zoiitally and makes the key liolcs in jxTt'orati'd latli. Bcyoud the jHiiieli 
 a revolvinjr knife euts tlie eontinuous strip into len^rths that are wliisked 
 away at an aeeelerated speed to the end of the machine. The distance 
 from the forming rolls to the ent-ofT knife ran«?es from nnder oOO feet 
 to over ()()U feet. 
 
 Drying is accomplished by passing the lengths back through a Coe 
 drier placed parallel with the board machine. A fully automatic system 
 of transfer belts moves them to an elevator or hinged loading ramp that 
 feeds them two at a time into the projier deck of the drier. The key hole 
 j)unch, the cut-off knife, the transfer belts, and the loading ramp are 
 synchronized and are controlled by switches actuated either by fingers 
 that contact the lengths of board or by electric eyes. 
 
 Driers have six or eight decks of rollers, each wide enough to accom- 
 modate two lengths of wallboard or six lengths of lath. They are divided 
 into three or four sections through which air is forced. Heat is provided 
 bv steam coils beneath the decks or bv gas burners in the air intakes. 
 Temperatures of 300^^ to 850 'F. are maintained in the first part of the 
 drier. This is reduced to 250°F. or less in the end .section to eliminate 
 the possibility of recalcining. 
 
 In some plants the finished wallboard and lath are unloaded and stacked 
 by e(|uipment similar to the loading ramp, but at other plants unloading 
 and stacking are done by hand. These operators feel that hand unloading 
 provides an opportunity for closely inspecting that justifies a possible 
 increased breakage caused by carelessness. 
 
 The following products are made by most board plants. 
 
 Gypsum Wallboard. Gypsum wallboard is for walls and ceilings. It 
 is fastened directly onto the wood framing or furring blocks and may be 
 painted or papered. ]\[ost wallboard is ^ inch thick, but there is ^-inch 
 wallboard also that possesses 40 percent greater strength. Both §- and 
 ^-inch wallboard are available in 4-foot widths and lengths of 6, 7, 8, 9, 
 10 and 12 feet. Both are available with recessed edges for u.se with rein- 
 forcing tape and cement to conceal the joints, beveled edges for decorative 
 effects, or square edges. There is also ^-inch wallboard for curved sur- 
 faces, repair work, or lining sheds that is available in lengths of 7, 8, 9, 
 and 10 feet. The ]-inch wallboard is made with scjuare edges only. 
 
 Gjfpaum Lath. Gypsum lath is ij inch or I inch thick, Ifi inches wide, 
 and 4 feet long. Lath has round edges. It is available either plain, per- 
 forated, or with a sheet of aluminum foil cemented to the back side for 
 insulation against heat and cold. 
 
 Gypsum Sheathing. Gypsum sheathing is a water-repellent, wind- 
 tight sheathing material intended for use without building paper. It is 
 made with special water-resistant paper and has tongue and groove edges. 
 Gypsum sheathing is available in sheets J inch thick, 2 feet wide, and 
 8 feet long. 
 
 Gypsum, Tile. Gypsum tile has been in use for over 30 years, but eon- 
 sumption is minor compared with that of other gypsum products used 
 by the building industry. 
 
 Tile is cast in steel molds by mass production methods. Standard tile 
 is 30 inches long, 12 inches wide, and available in a number of thicknesses. 
 There are also specially shaped tiles for use as shoe and soffit tile with 
 
 13—58771 
 
94 GYPSUM IN CALIFORNIA [Bull. 163 
 
 structural steel. Solid tile 2 iuches and 3 inehes thiek is available, and 
 hollow tile, whieh contains symmeti-ically spaced holes i)arallel to the 
 leno-tli, is available in 3-, 4-, 5-, aiul B-inch thicknesses. Furring blocks 
 H inch or 2 inches thick are made by s]dittiii<i- hollow tile. Tile is readily 
 cut with the plaster saw, which has large teeth. Only gypsum mortar, 
 which consists of neat plaster mixed with up to 3 parts by weight of 
 sand, can be used with tile. 
 
 The principal uses for gypsum tile are for non-load-beariiig interior 
 partitions and for fireprooting structural steel. Gypsum tile is particu- 
 larly adapted to buildings in which partitions must be frequently altered 
 to meet changing requirements. In protecting steel beams, columns, and 
 girders from fire, 2- or 3-inch tile are built around the member. Hollow^ 
 spaces may be backfilled, and additional protection is provided by plaster- 
 ing the outside. In tests made bv the Bureau of Standards loaded test 
 columns protected with gypsum tile and subjected to a temperature of 
 2200° P. failed after 2^ to nearly 7 hours. The thickness of the tile, the 
 use of solid or hollow tile, and the presence of plaster account for this 
 range in time to failure. 
 
 Reinforced Gypsum Concrete 
 
 Reinforced gypsum concrete is a building material used in compara- 
 tively small quantities that was approved for use in 1941. It consists of 
 plaster mixed with up to 12| percent by weight of wood fiber, chips, or 
 shavings ; and it is reinforced with concrete reinforcement bars or wire. 
 Minimum compressive stresses specified by the American Standards As- 
 sociation are : 
 
 ]\Teat 1800 pounds per square inch 
 
 Containing up to 3 percent wood fiber 1000 pounds per square inch 
 
 Containing up to 12 percent wood fiber 500 pounds per square inch 
 
 Reinforced gypsum concrete is either used as precast units or cast in 
 place. Roof tile is 3 by 12 by 30 inches. Gypsum planks are either plain 
 edged or have metal tongue and groove edges. The plain edged planks are 
 2i inches thick, 10 inches wide, and 6 feet long. Metal edged planks are 2 
 inches thick, 15 inches wide, and 6, 8, or 10 feet long. 
 
 AVhen reinforced gypsum concrete is poured in place two systems may 
 be used. In one a permanent form of wallboard is built, steel reinforce- 
 ment is placed, and the gypsum concrete is poured on it. In the suspension 
 system parallel and uniformily spaced cables are stretched over the roof 
 or floor beams and securely anchored at the ends. Forms are placed be- 
 neath the cables, and at least 3 inches of gypsum concrete is poured, 
 enclosing the cables. 
 
 Industrial Plasters 
 
 A comparatively small volume of high priced calcined gypsum products 
 is produced for industrial use. Some are specialties that are made at 
 only a few plants for the entire United States market ; others, used in 
 greater (luantities, are produced by the majority of plaster manufac- 
 turers. In general, industrial plasters have higher strength than most 
 building plasters and medium to quick setting times. 
 
 Strength of plaster is closely related to consistency because a plaster 
 of high consistency is porous after it has set and dried. Ordinary plaster 
 is mixed with a quantity of water enormously greater than that required 
 
Part 2] MIXING, PROCESSING, AND MARKETING 95 
 
 for liydratiuu. The iinnual eun.sisteney of lianhvall plaster is 80 to 100 
 milliliters of water per 100 {j:rams of plaster, while the theoretieal amount 
 of water for rehydration is only 18.6 milliliters. By artificial aginf?, the 
 normal consistency of UcttK* stucco can be reduced to between (iO and 75 
 milliliters. A<rcd stucco rej^round with bnhr mills is used for some indus- 
 trial plasters. 
 
 There are a number of patented methods for producinj,' hi<rh-strength 
 plaster of very low consistency. Ilydrocal is made by treating: lump 
 jrypsum in an autoclave with saturated steam at 15 pounds pressure for 
 6 hours. The calcineil protluct, after drying and «rrindinj>:, has a consist- 
 ency of 45 milliliters. Certrock is kettle stucco to which is added 1 to 2 
 percent of jrum arable and an alkali such as lime, litliar<re, or soda ash. 
 The consistency approximates that of Ilydrocal. Ilydrostone, made by 
 treating Ilydrocal with gum arabic and alkali, has a consistency of 27 
 milliliters. In making llydromite a carbamide-formaldehyde resin is 
 added that still further reduces the amount of excess water taken up 
 by the ])laster. A ju-ocess developed by Eberl and Ingram ^^ consists of 
 autoclaving a slurry of finely ground gypsum to which is added about 
 0.1 percent of a dicarboxylic acid salt. Microscopic studies showed that 
 tliese salts cause the luMuihydrate crystals to have the shape of short rods 
 that can pack closely. A limited amount of grinding following autoclaving 
 increases the powder density, apparentl}' by rounding the sharp corners 
 of the crystals ; but prolonged grinding produces fluffy particles. 
 
 Casting Plaster. Casting plaster is used for ornamental statuary and 
 interior decoration because it expands slightly upon setting. The prop- 
 erties desired are high strength, low heat of hydration in order not to 
 harm the molds, and (piick setting time. It is prepared by regrinding 
 artificially aged kettle stucco. 
 
 Pottery Plaster.^'' Pottery plasters are special plasters used by the 
 ceramics industry in the manufacture of dinner ware and sanitary ware. 
 They are used as modeling and patterning mediums and in making master 
 dies and production molds. Gypsum plaster is suitable for these purposes 
 because of its ability to receive aiul transmit to other media surface 
 detail, to retain dimensional accuracy, and to absorb moisture. 
 
 Pottery plaster is a plaster of low consistency and high strength. Since 
 1032 a number of special pottery plasters have been developed that con- 
 tain a high proportion of alpha ('aS()4-UL.O. In compressive strength 
 they range up to 15,000 pounds per square inch, in expansion from 0.0 
 percent to 1.5 percent and in absorption characteristics from 2 percent 
 to more than 50 percent. Improvements in pottery plaster have made 
 possible improvements in nu)ld shop practice. 
 
 In pottery plants particular attention should be paid to the storage 
 of plaster to prevent its absorbing moisture. Enclosed storage to prevent 
 the free circulation of air should be provided, and the temperature 
 should be kept above the dew-point. Mixing is usually done with me- 
 chanical mixers to produce slurries free from entrained air, and in a 
 few cases vacuum mixing is practiced. New molds are dried before use, 
 
 ** Eberl, J. J., and Ingram, A. R., Process for making high-strength plaster of Paris : 
 
 Ind. and Eng. Chem., vol. 41, pp. 1061-1065, May 1949. 
 8= Wiss, J. E., Recent developments in the use of gypsum plasters in ceramics : Pacific 
 
 Coast Ceramic News, vol. 1, no. 10, pp. 13. 17, April 1951 and vol. 1, no. 11, p. 14, 
 
 May 1951. 
 
96 GYPSUM IN CALIFORNIA [Bull. 163 
 
 and used molds are dried before being used again. In storing molds slow 
 calcination may take place if the temperature is greater than 120° F. 
 and the relative humidity is less than 10 percent. 
 
 Plaster for the Plate Glass Industry. The plate glass industry uses 
 plaster for hohling the glass during polishing. Plaster for this purpose 
 mu.st be finely ground and contain no impurity that could scratch the 
 glass. Strength is relatively unimportant. 
 
 Dental and OrUiupcdic Plasters. I'nited States consumption of dental 
 and orthopedic plasters is only a fcAv thousand tons a year. Dental 
 ])lasters have high tensile strength and are available with setting times 
 ranging from 2 to 40 minutes. Low heat of hydration is essential. 
 
 Industrial Casting and Molding Plasters. Special high-strength plas- 
 ters such as Hydrocal are used for tooling and pattern work requiring 
 great dimensional accurac^^ For less exacting work casting plaster made 
 from kettle stucco is used. 
 
 Minor Uses of Gypsum 
 
 In addition to its principal uses, small (quantities of gypsum totaling 
 less than 50,000 tons a year for the entire Ignited States are consumed 
 for other purposes. Finely ground, white, uncalciued gypsum, called 
 terra alba, is a cheap material that is chemically neutral. As a filler, it is 
 used in paper, textiles, paint, plastic articles, and blasting powder. As a 
 diluent and carrier, it is mixed with drugs and chemicals. Kelatively 
 small quantities compared with talc and pyrophyllite are used in insec- 
 ticides. Crown filler, artificially precipitated CaS04 -21120, is used in 
 paper and cloth. Breweries use powdered gypsum for conditioning water. 
 Mixed with a binder, powdered gypsum is made into blackboard chalk. 
 
 An industrial drying agent is prepared by calcining gypsum for 3 
 hours at 460° F. The product, which is soluble anhydrite, can be regener- 
 ated by reheating. Calcined gypsum is also used as a fireproof filling for 
 safes and filing cabinets and as an ingredient of match heads. 
 
 In some countries, but not in the United States, substantial quantities 
 of gypsum are used in metallurgy and in chemical processes. It is used 
 as a flux in smelting the nickel ores of New Caledonia, in the Carmichael- 
 Bradf ord processes for the blast roasting of galena, and for concentrating 
 lead-copper matte in Germany. 
 
 In England, France, and Germany ammonium sulfate is prepared by 
 reacting ammonia and carbon dioxide with ground gypsum in water'. 
 After the calcium carbonate that precipitates has been removed, the 
 solution is evaporated to recover the ammonium sulfate. 
 
 The current sulfur shortage has created reiu^wed interest in gypsum as 
 a source of sulfur compounds, and there are a number of processes for 
 making sulfuric acid from gypsum or anhydrite. An English plant is 
 described in the anhydrite section of this paper. Mo.st of the processes 
 produce cement clinker and SGj gas that is made into sulfuric acid, but 
 recently a United States patent has been issued on a process ^^ in which, 
 by means of a catalyst, hydraulic cement and sulfur trioxide are 
 produced. 
 
 In India the recovery of sulfur from gypsmn is under consideration.^" 
 
 ** Rook Products. New products from gypsum : Rock Products, vol. 54, no. 2, p. 77, 
 
 February 1951. 
 ^ Chem. and Eng. News, India may produce sulfuric acid from gypsum : Chem. and Eng. 
 
 News, vol. 29, no. 5, p. 392, 1951. 
 
Part 2] MINING, PROCESSING, AND MARKFTINO 97 
 
 Uses of Anhydrite 
 
 Anhydrite, commonly associated with jrypsum, is found in most of the 
 extensively developed {ryjisum deposits. In California abiindant anhy- 
 drite has been enconntcrci] only in the workinjis of the United States 
 (iyi)sum Company in the Little Maria ^Fountains and in the Fish Creek 
 Mountains. Other deposits where further exploration might reasonably 
 be expected to find anhydrite are the Palen Mountains, Riverside Moun- 
 tains, and Cuyama Valley de]iosits. 
 
 Althougli many gypsum mines could ])roihu-e large quantities of 
 aidiydrite, few uses for anhydrite have been developed; and compara- 
 tively small quantities are sold. For some purposes anhydrite can be 
 substituted for gypsum. Probnbly the largest amount is used in agricul- 
 ture. Aidiydrite from Xova JScotia is used as a source of calcium and 
 sulfur for peanut crops in Virginia. Tn California some high grade 
 agricultural gypsum contains anhydrite. The treatment of alkali and 
 adobe soils with anhydrite has nM-iuved little study, although the ex- 
 periments of (J. E. Colby ^^ showed that both anhydrite and gypsum are 
 equally effective in neutralizing black alkali (sodium carbonate). The 
 State Bureau of Chemistrv has noticed no indication that anhydrite and 
 
 • « 
 
 gypsum are not of ecpial value, and as yet it has not been necessary to 
 distinguish between them. 
 
 The Portland cement industry has devoted much study to the substi- 
 tution of anhydrite for gypsum as a retarder. Today anhydrite is not 
 used generally, although one California portland cement producer has 
 used sul)stantial (luantities of anhydrite. The jiublished reports of the 
 studies made appear to be incomidete and inconclusive, but all investi- 
 gators agree that anhydrite cannot be indiscriminately substituted for 
 gypsum even though the sulfate radical is the active component of the 
 gypsum. Presunud)ly differences in solubility and rate of dissolution ac- 
 count in part for the differences in their behavior. Laboratory experi- 
 ments ^^ do show that for some cements between 25 and 70 percent of the 
 sulfate added may be in the form of anhydrite. 
 
 Anhydrite may be advantageously substituted for gypsum in most of 
 the chemical and metallurgical processes requiring calcium sulfate be- 
 cause of its higher calcium sulfate content and lack of water of hydration. 
 Tjittle if any calcium sulfate is. however, so used in the T'nited States. 
 
 In Cermany and England large quantities of both gypsum and anhy- 
 drite are used in making ammonium sulfate. At liillingham, England both 
 sulfuric acid and portland cement are made from anhydrite in an inte- 
 grated operation."" Anhydrite is reduced to sulfur dioxide with coke in 
 a cement kiln, and the correct amount of clay and siliceous material is 
 added so that the residue has the composition of portland cement clinker. 
 The sulfur dioxide is purified and converted to sulfuric acid. 
 
 ]\Iuch Avork has been done on making plaster from anhydrite, and some 
 anhydrite plaster is used in England. Finely ground anhydrite sets very 
 slowly with water, and most of the investigations have been concerned 
 
 f^^Colbv, G. E., A note on the use of anhydrite as a remedy for black alkali : California 
 
 Dept. Agriculture Bull. 10, no. 1. pp. 39-41, 1921. 
 »• Hansen, W. C, and Hunt, .1. O., The u.«e of natural anhydrite in portland cement: 
 Am. Soc. Test. Material.s, Bull. no. 161, pp. 50-.57, October 1949. 
 Roller, P. S., and Hahver, Murray, Relative value of gypsum and anhydrite as addi- 
 tions to Portland cement : U. S. Bur. Mines Tech. paper no. 578, 15 pp., 1937. 
 »Stewart, G. K., Billingham mine: Inst. Min. Met. Bull. 480, pp. 1-11, Sept. 1946. 
 Cole, L. H., and Rogers, R. A., Anhydrite in Canada : Canada Dept. of Mines, Mines 
 Branch, no. 732, p. 30, 1933. 
 
98 GYPSUM IN CALIFORNIA [BuU. 163 
 
 with the addition of siiitablo accolerators. The Canada Department of 
 Mines conducted an exhaustive series of laboratory tests ^^ on makiiifi: 
 plaster from anhydrite from numerous Canadian dojiosits. By the addi- 
 tion of small (piantities of metal salts to finely ground anliydrite, plasters 
 were made having approximately the properties of Keene's cement. Many 
 of the reagents tested produced plasters with high shrinkage and great 
 efflorescence, but the most satisfactory results were obtained when two 
 reagents were used. The tests indicated further that anhydrite from 
 different deposits required different proportions of reagents. 
 
 Some work has been done on making high strength cement by calcining 
 anhydrite. 
 
 Other minor uses for anhydrite are for some fillers, carriers, and dilu- 
 ents. Pearl filler is finely ground anhydrite. 
 
 Gypsum Markets 
 
 Gypsum, like many non-metallic minerals, is a low-priced, widelj^ dis- 
 tributed commodity that is of value only when it may be economically 
 transported to consuming centers. Freight charges represent in many 
 cases half or more of the price the consumer pays. Although there are 
 large undeveloped gypsum deposits in the state, California production 
 is estimated to be but three-quarters of consumption. Most of the gypsum 
 produced in California is consumed in the southern part of the state, and 
 even in southern California appreciable quantities of gypsum are brought 
 in from Mexico and Arden, Nevada. Northern California is supplied al- 
 most entirely with gypsum from Mexico and Gerlach, Nevada. 
 
 The California production of gyjisum is shown in figure 10. Since sta- 
 tistics were first recorded in 1887, the production has reflected the growth 
 in population and in industrial activity. Most outstanding is the enormous 
 increase within the past 10 years, which was caused both by a sharp rise 
 in building activity and by the large scale use of gypsum for treating 
 alkali soils that began about 19-40. 
 
 The plaster industry, agriculture, and the portland cement industry 
 are the major consumers of gypsum in California. The pla.ster industry is 
 dominated by large integrated companies that own their own gypsum 
 mines and have reserves for many years. Competition between companies 
 and between the plaster industry and manufacturers of other building 
 materials is keen. Large amounts of capital are required for the construc- 
 tion of calcining and wallboard plants. Expenditures of 1^ and two mil- 
 lion dollars have been reported "- for the building and reconstruction of 
 plants outside of California. 
 
 In California there are five calcining plants. One is in the San Francisco 
 Bay area, two are near Los Angeles, and the remaining two are in the 
 southeastern desert close to gypsum deposits. The three metropolitan 
 plants obtain gypsum from outside of the state. The Bay area plant and 
 one of the Los Angeles plants produce board products only. In addition, 
 plaster and board products are brought in from Gerlach and Arden, 
 Nevada. 
 
 Most of the agricultural gypsum is consumed in tlie San Joaquin 
 Valley. Ninety percent of this gypsum is gypsite produced within 150 
 
 *• Cole, L. H., and Rogers, R. A., Anhydrite in Canada : Canada Dept. of Mines, Mines 
 
 Branch, no. 732, pp. 35-80, 1933. 
 92 Mining M'orld, vol. 11, no. 7, p. 50, June 1949. 
 Pit and Quarry, vol. 41, no. 7, p. 98, January 1949. 
 
Part 2] 
 
 MININO. I'ROl'ESSINO. AND M AHKKTINfJ 
 
 99 
 
 » 
 
 
 d 
 
 §4 
 
 ■V 
 
 \ 
 
 \ 
 
 V 
 
 \ 
 
 -^. 
 
 CAUFORNIA 
 GYPSUM PRODUCTION 
 - AMOUNT a AVERAGE VALUE 
 PER TON 
 
 \ 
 
 
 .r- 
 
 \ 
 
 \ 
 
 A 
 
 A 
 
 ii 
 
 / 1 
 / 
 
 r 
 
 TONS GYPSUM ►/ 
 
 / 
 
 f 
 
 jmOTPERTO/V 
 
 'V 
 
 .A 
 
 -x^-A 
 
 / 
 
 V- 
 
 /^ 
 
 7' 
 
 10 
 
 2S 
 
 455 
 
 3i 
 
 1885 1890 1895 1900 1905 1910 1915 1920 1925 1930 1935 1940 t945 1950 
 
 FiGUKE 1 0. Chart showing production and average price of gj'psum in California. 
 
 miles of the farms; the remainder is ground rock gypsum most of which 
 is mined in southern California. p]lsewhere in California, ground roek 
 gypsum is used exclusively. That sold in northern California comes from 
 Nevada, while gypsum sold in the Imperial Valley is produced in Cali- 
 fornia. 
 
 The agricultural market is relatively favorable for the snuiU producer. 
 Producers must, however, comply with the regulations of the Department 
 of Agriculture, which are discussed in another section of this study. The 
 mortality among producers of agricultural gypsum has been high and 
 probably the greatest single cause is failure to produce gypsum of the 
 guaranteed ([uality. 
 
 Most of the Portland cement plants purchase gypsum from plaster 
 companies. Only two California plants obtain gypsum from their own 
 deposits, and of these, one is a nuijor producer of calcined gypsum prod- 
 ucts as well as portland cement. In addition, two companies own deposits 
 from which there has been no production. Plants in northern California 
 use gypsum from Mexico, and Gerlach, Nevada, supplemented by syn- 
 thetic gypsum made in the Bay area, while southern California plants 
 use g3-psum from California and Arden, Nevada. 
 
 The Portland cement industry is a relatively unfavorable market for 
 the small gypsum producer. Portland cement plants desire a uniform 
 and dependable sujiply of gypsum, and numy are reluctant to jeopardize 
 their existing sources unless a long-term guarantee is furnished. The 
 producer must also find a market for off -grades and sizes of gypsum that 
 are not acceptable to the portland cement plant. 
 
 Although the average value of gyjisum at the mine is reported to be 
 $2.45 a ton b^' California producers, most figures for rock gjT)sum are 
 
100 GYPSTTM IN CALTFORXIA [BuU. 163 
 
 nominal. The only California prodnetion costs available are those of the 
 Tnoa operation, which is described in another section of this study. There 
 the cost of mining was $1.50 a ton. Preparation of bulk gypsum (ground 
 to 100 percent minus 10 mesh) cost less than $1.50 a ton, and sacked 
 gypsum (100 percent minus 50 mesh), $4.50 a ton. 
 
 The price of gypsite is about $1.75 a ton at the mine. 
 
 Freight charges are equal to or greater than the price at the mine. 
 The following representative rates on crude gypsum were in effect in 
 February 1951.93 
 
 Rail carload rates (in cents jjer 100 pounds or per ton in open top cars). 
 
 Minimum 
 ■\vpi};ht 
 To From Rate (cents) (pounds) KouKirUs 
 
 Los Angeles Midland 324 per ton 40,000 
 
 Midland 292 per ton 80,000 Santa Fe direct 
 
 Plaster City ___ 324 per ton 40,000 
 
 Plaster City ___ 292 per ton 80,000 
 
 Maricopa 15 per 100 pounds 30,000 
 
 Fresno Midland 454 per ton 40,000 Santa Fe direct 
 
 Midland 497 per ton 40,000 Does not apply via 
 
 Santa Fe direct 
 Plaster City ___ 454 per ton 40,000 San Diego-Ariz., via 
 
 r]l Centro, South- 
 ern Pacific 
 
 Plaster City 497 per ton - 40,000 San Diego- Ariz., via 
 
 VA Centro South- 
 ern I'acific, (\)1- 
 ton or Bakersfield, 
 Santa Fe 
 San Francisco Maricopa 28 per 100 pounds ■ 30.000 
 
 Truck Load Rates 
 
 jMinimum 
 
 Avoight 
 To From Rate (cents) (poundsl Remarks 
 
 Los Angeles _ Midland 18 per 100 pounds 40.000 Dock to dock 
 
 Midhind 24A per 100 pounds 40,000 If no rail track or 
 
 truck dock 
 
 Plaster City __. 21 per 100 pounds 30,000 
 
 Maricopa 19 per 100 pounds 40,000 
 
 Fresno Midland 52 per 100 pounds 40.000 Dock to dock 
 
 Midland 58 p.T 100 pounds 40.000 If no rail track or 
 
 truck (lock 
 
 Plaster {^ity __ , .30 jicr KM) i.ounds .'iO.OOO 
 
 San {■'rau<is(() .Maricopa 00 per 100 pounds 40,000 
 
 Agricultural gypsum may be sold at the mine, but the price usually 
 includes delivering the gypsum to the farm and sometimes spreading 
 it on tlie fields. In the San Joacpiin Valley 50 to 70 percent gypsite costs 
 between $().()() and $7.00 a ton delivered and spread. Ground rock gypsum 
 costs $14.00 a ton delivered or up to $18.00 a ton if the cost of spreading 
 is included. It is apparent tliat the cost of liauling and handling agri- 
 cultural gypsum is several times its value at the mine. Considering the 
 cost per unit of gypsum, the handling charges of gypsite increase rapidly 
 with decreasing gypsum content. At a comparatively short distance from 
 
 »3 Data supplied by W. G. O'Barr, Los Angeles Chamber of Commerce. 
 
Part 2] MININC, PKOCEiSSING. AND MAKKKTINO 101 
 
 the mine the post per unit of {gypsum in jrypsite ecjuals that of high-grade 
 rock gypsuni. Actually 70 jicrceiit fryi)sitc from Kciii County is sold as 
 far nortli as Livcrmore. In a similar way, the 'M) and 40 ]icrccut gypsitc 
 from F'resno County has a still more limited range. 
 
 GYPSUM PLANTS IN CALIFORNIA 
 
 Kalscr (Ijip.sinn Dirisioit, Lmuj iiiach I'hnit '" ( .14 ) . The Long Beach 
 l)lant of Kaiser (Jyi)sum Division of Kaiser Intlustries Inc. is at I'MU 
 Water Street on the Long Beach waterfront. The property was purchased 
 from the Standard Cypsum Company in 1044. and enlargement and 
 modernization was completed in the summer of ]!)47. The chief prcxlucts 
 are gyi)sum walllioani and lath, hardwall plaster, gaging plaster, and 
 finishing i)laster. 
 
 Raw gypsum is brought from the Kaiser Company's San Marcos 
 Island deposit in the self-unloading ship "Permanente Silverbow." The 
 gypsum, a hard, fine-grained material crushed at the mine, contains so 
 little free moisture that drying before grinding is not necessary. Covered 
 storage is provided at the plant. 
 
 Cypsum from the stock jnle is crushed in a Pennsylvania hammer mill 
 and then ground to about 78 percent minus 100 mesh with Raymond 
 liigh-side roller mills in closed circuit with air separators. The Raymond 
 mill product is fed to three gas-fired Ehrsam calcining kettles, each of 
 10 tons capacity. The calcining time is about 2| hours, and the maximum 
 tempei-ature is between lUO"" and 8o0° F. The kettles are equijiped with 
 recoi'ding pyrometers to facilitate close temperature control. After cal- 
 cination the kettle charge is dumped into the hot pit. When it has cooled 
 the stucco is elevated to bins in the plaster section of the mill or carried 
 to th(> wallboard section with S-iuch screw conveyors. Because of the 
 j)lant's location in an intensely developed area, special precautions are 
 taken to avoid contaminating the atmosphere with dust. Air from the 
 Raymond mills passes through (doth filters after leaving the air separa- 
 tors. Eacii hotpit is -seuted to its kettle, and the kettle stacks are equipped 
 with water sprays that wash the dust out <»f the mixture of dust and 
 steam given off during calcination. 
 
 Stucco for hardwall plaster is reground in a Marcy 5 x 20-foot tube mill, 
 while stucco for casting plaster is reground in liulir mills in closed circuit 
 with Whizzcr dust sepai-ators. Reground stucco is conveyed to bins located 
 above weighing hojipers where retarder. fiber, aggregate, or other ingredi- 
 ents are added, (^ne-ton batches from the weighing hoppers are mixed 
 for 3 minut(>s in Ehrsam paddle-tyjie mixers and then packed in 100- 
 pound paper bags. 
 
 Gypsum board products are made on a 493-foot machine designed 
 cooperatively by the J. B. Ehrsam and Sons Manufacturing Company 
 and the Henry J. Kaiser Com]iany. Stucco is taken directly fi'om the 
 hotpits to the board i>lant with screw conveyors and stored iu cylindrical 
 tanks with conical bottoms. Stucco from the storage tanks passes through 
 a mixing screw conveyor where dry ingredients are added with Syntron 
 electric vibrating feeders. Water is added in a pin-type mixer at the head 
 
 ** Newest plaster board plant on west coast : Rock Products, vol. 50, no. 9, pp. 74-77, Sep- 
 tember 1947. 
 
 Utley, F. H., "World's richest gypsum quarry" supplies new board plant: Pit and 
 Quarry, vol. 40, no. 3, pp. 114-117, 124, September 1947. 
 
 Plant visit January 1949. 
 
102 GYPSUM IN CALIFORNIA | l>ull. 163 
 
 of the machine. The fjreen board from the forming rolls is supported for 
 255 feet on a 57-in('h eonveyor belt and tlicMi on I'ollcrs. Th(> punch for 
 making holes in perforateil lath and the eut-otf knife are of the Ehrsam 
 type. The punch, knife, transfer section, and loading ramp for the drier 
 are synchronized Avith Selsyn and electi-ic eye controls. Board is dried in 
 a Coe drier having eight decks. Finished board is removed by hand, 
 inspected, and bundled. 
 
 Kaiser Gypsum Division, Rcdirood City Plant '^^' (08). The Redwood 
 City plant of the Kaiser Gypsum Division, Kaiser Industries, Inc., manu- 
 factures gj^psum board and lath products for the Bay area and the north- 
 ern California market. Ernest Schaper is the plant superintendent, the 
 superintendent of the wallboard plant is Lawrence E. Hays, and Wallace 
 C. Riddell is Director of Researcli. Built by the Pacific Portland Cement 
 Company in 1941, the plant was taken over by the Kaiser interests in 
 October 1949. It is located at the Port of Redwood City where crude 
 gypsum is brought in Kaiser ships from the San Marcos Island deposit 
 and stockpiled near the plant. 
 
 The crude gypsum as received at the wallboard plant is 2 to 3 inches in 
 size and averages 96^ percent gypsum. Trucks deliver it from the stock- 
 pile to a hopper from which it is fed to a jaw crusher that reduces it to 
 half-inch size. The former operator calcined a mixture of natural and 
 synthetic gypsum, but this practice has been abandoned. It is believed 
 that difficulty encountered in calcining the synthetic material may have 
 been caused by a coating of magnesium hydroxide. 
 
 Calcining is accomplished with three number 50 Raymond Imp kiln 
 mills driven at 1850 rpm by 50-and 60-horsepower motors. The tempera- 
 ture of the furnace gases is 1400^F., and the stucco is withdrawn from 
 the mills at 360° to 410°F. and 90 to 95 percent minus 100 mesh. Stucco 
 is stored in cylindrical steel storage bins. 
 
 Stucco is Avith drawn from the bins with drag conveyors, passed through 
 a revolving half-inch screen to remove foreign matter, and brought to 
 the mixing platform over the head of the Ehrsam board machine. Care- 
 fully measured amounts of additives are introduced into the screw con- 
 veyor with Gump feeders located on this platform. An Ehrsam type pin 
 mixer is used to mix the dry ingredients with water. This board machine 
 is provided with guides placed at intervals to keep the board in position. 
 Talc powder is put on the top surface of the board to facilitate later 
 handling. The switches that control the cut-off knife, transfer belts, and 
 loading ramp are actuated by fingers that contact the lengths of board. 
 
 The Coe drier has six decks and is divided into three sections. Heat is 
 provided by steam coils in the first and second sections and by gas burners 
 in the air intakes to the second and third sections. The temperature in 
 the first section is from 320' to 350^" F., about 360 -F. in the second, and 
 250°P. in the third. Finished Avallboard and lath is removed from the 
 drier, inspected closely for quality defects, placed face to face ; and the 
 ends are sealed with paper tape. Then the bundles are placed in the Avare- 
 house or stacked in box cars for shipment. 
 
 At present the plant is operating 24 hours a day, 7 days a week, at a 
 capacity that has been increased nearly 50 percent during the past year. 
 
 ^ Plant visit January 1951. 
 
Part 2] MINING. PROCESSING, AND MARKETING 103 
 
 MoHitlith /'(jrtl(i)i(l ('(iiKiit ('oiiipaiu/, (Juatal ('(iniit/n (ii/psuni Opcra- 
 tion'-*'' (109). Till' Qiiatal Canyon jrypsuni oi)i'rati(Hi of the Monolith 
 Portland Cement Company is on the north side of Qnatal Canyon about 
 .') miles east of \'entU('opa. a post office and store in the upper Cuyama 
 Valley. (Jyiisum for the company's poi-tland cement jilant at Tehachapi 
 is prothiced here. Mining hejran in 11*41. 
 
 The gypsum bed has been opened by two small (piarries in a branch 
 canyon close to the lower edfre of an extensive dip slope. The bed is 10 
 to 15 feet thick here, and it is covered by up to lo feet of soft clay shale. 
 After the overburden has been removed with bulldozers, the gypsum is 
 drilled with jackhanuners and blasted. A power shovel loads the gypsum 
 into dump trucks for the haul to the crushing plant about a ([iiarter of 
 a mile away near the mouth of the branch canyon. 
 
 At tlie crushing plant the trucks dump the gypsum on a grizzly with 
 widely .spaced bars; and the oversize is broken uj) on tlie grizzly with an 
 air operated gad. The gypsum then ])asses over a second grizzly, and the 
 oversize is reduced to about H inch with a jaw crusher. The crusher 
 product and grizzly undersize are stockj)iled over a timbered draw point 
 by means of a belt conveyor. A second belt conveyor is used to load trucks 
 from the draw ]ioint. The ci'ushed gyi)su!n is hauled in large diesel trucks 
 with trailers to Marico])a where it is loaded into railroad i-ars that take 
 it to Tehachapi. 
 
 Montcri'ii (inpsuin Contpait})''' (76). The ^Monterey Gypsum Com- 
 pany was the most recent of a number of enterprises that operated the 
 Mule Shoe Ranch deposit, San P>enito County. During 1945 and 1946 
 ground rock gypsinn for agricultural use was jn-oduced in a plant just 
 west of the Bitterwater road 14 miles from King City. The product was 
 guaranteed to contain 85 percent CaS0,-2n:.0. The operation is aban- 
 doned and the e(|nipm(Mit removed. 
 
 The gypsiun body worked in 1945 was a flat-lying lens near the top of 
 a low ridge half a mile north of tlie plant. Up to 8 feet of slightly consoli- 
 dated overburden was stripped before the gypsum was drilled and bla.sted. 
 A truck-mounted crane eipiipped with a !J-cubic-yard clam shell bucket 
 loaded the broken gypsum into a triu'k of 6 cubic yards capacity. 
 
 At the plant the gypsum was crushed to 4-to-6-inch size in a 15- by 38- 
 ineh jaw crusher and ground to 90 percent minus 100 mesh in a Gruenler 
 hammer mill in closed circuit with a Raymond air separator. Shipments 
 of both bulk and sacked gypsum Avere made. Capacity of the plant was 
 200 tons in 8 hours. 
 
 Pabco Prodiicfs, Inc., SoHth ante Board Plant "^ (57). The Paraffine 
 Companies, Inc. produces Pabco wallboard, lath, and sheathing board in 
 a plant at 4231 Firestone Boulevard, South Gate. Gypsum is brought by 
 rail from the company's deposit near Las Vegas, Nevada. The small 
 amount of impurities contained in the gypsum consists primarily of 
 limestone. 
 
 At the plant the gypsum is screened after magnets remove tramp iron. 
 Plus f-inch material is ground in a Williams mill, and the ground gypsum 
 goes to storage bins. Stucco is produced in four Raymond Imp kiln mills. 
 
 »9 Plant visit Mav 19.50. 
 
 "Avenll, C. V., Mines and mineral resources nf San Benito County, California: Califor- 
 nia Jour. Mines and GeologTJ', vol. 43, p. 51, 1947. 
 »* Plant visit January 1949. 
 
104 GYPSUM IX CALIFORNIA [BuU. 163 
 
 Gases and steam from the cyclone separator pass through a Cottrell pre- 
 cipitator for the removal of dust before being discharged into the at- 
 mosphere. 
 
 Board products are made on an Ehrsam machine. The dry additives 
 are measured into the screw convej'or that brings the stucco to the pin- 
 type mixer where water is added. When lath is made the cut-off knife 
 scores the lath every four feet and cuts it into 12-foot lengths. The long 
 sections are broken into four-foot lengths as they come from the drier. 
 The drier, a Coe machine, has eight decks and is divided into three sec- 
 tions. The finished lengths are taken from the drier, alternate sections 
 turned over, and stacked mechanically. 
 
 United States Gypsum Company, Plaster City Plant (28) . One of the 
 largest gypsum plants in California is the Ignited States Gypsum Com- 
 pany's operation at Plaster City, Imperial County. Gypsum is brought 
 by rail from the company's quarry in tlie Fish Creek ]\Iountains about 
 25 miles to the north. The United States Gypsum Company bought the 
 plant and deposit from the Pacific Portland Cement Company in 1945 
 and has since rebuilt and modernized the entire operation. H.E. Hammer 
 is AVorks Manager and J.R. Burns is Quarry and Railroad Superin- 
 tendent. 
 
 No recent description of the quarry or plant is available. The deposit 
 has been opened by a quarry that in 1942 had a face 3000 feet long and an 
 average height of 100 feet above the quarry floor.^^ Several months' sup- 
 ply of gypsum was shot down at one time by blasting a series of holes 
 drilled with an Armstrong churn drill. 
 
 United States Gypsum Company, Midland Operation ^^^ (68). The 
 United States Gy])sum Company's i)lant at ^lidland. Riverside County, 
 began producing uncalcined gypsum products in 1925. Calcined products 
 were first produced in 1928 in a plant that has since been enlarged. Gyp- 
 sum comes from the Brown, Victor, and Skeleuger mines 1 to 2 J miles to 
 the west and southwest in the Little Maria Mountains. Mr. IM.C. Grisham 
 was Works Manager in 1951. 
 
 At the Brown mine a gypsum lens that averages 45 feet wide and dips 
 75° NW. occurs in limestone north of tlie contact of the limestone with 
 the green schistose rocks. Anhydrite was encountered at a comparatively 
 shallow depth. The upper part of the gypsum body was mined by an 
 open cut 500 feet long and 50 feet wide ; the lower part was recovered by 
 over-hand stoping from an inclined shaft sunk to the anhydrite. In 1948 
 preparations were being made to remove the pillar beneath the pit floor 
 and abandon the mine. Gypsum is hauled to the plant in 3-ton mine cars. 
 
 In the Victor mine two gypsum beds 20 to 60 feet thick that dip about 
 30° NW. have been opened by tunnels. The gypsum beds are separated by 
 quartzite. and the gypsum and quartzite are interbedded with limestone. 
 Anhydrite occurs abundantly at depth and is found at some places within 
 30 feet of the surface. The gypsum is mined from open stopes driven on 
 25-foot centers from the tunnels to the surface. About 40 percent of the 
 gypsum is left in pillars that are to be mined later. Drilling is done with 
 
 w Sampson, R. J., and Tucker, W. B., Mineral resources of Imperial County : California 
 
 Div. Mines Kept. 38, p. 135, 1942. ^,.^ 
 
 100 Tucker W B , and Sampson, R. .1., Mineral resources of Riverside County: California 
 Div. Mines Rept. 41, pp. 170-172, 1945. - 
 
 Tucker, W. B., and Sampson, R. J., Riverside County : California Div. Mines and Min- 
 ing. Rept. 25, pp. 513-515, 1929. 
 Plant visit February 1948. 
 
Part 2] MINING, PROCESSING, AND MARKI:TI.\(! lOf) 
 
 liamiiuT drills run dry. IJruktMi jrypsuni is scraped Iroiu the stupes with 
 Sullivan sltishers and trammed to bins at tlio entrance to tlie haida{j:e 
 luiinel. 
 
 The Skelenjrer mine is an open jtit operation. fJypsnm bodies 60 to 150 
 feet thick and ui) to TOO feet lontr oeeur in limestone and dip at angles 
 of 20° to 35" NW. Gypsum from the Victor and Skelengrer mines is 
 trucked to the plant at Midland where calcined and uncalcined products 
 are made. 
 
 At tile plant, gypsum is first crushed in a "Williams hannner mill ami 
 then ground in Raymond mills. There are three calcining kettles, most 
 of whose output is used in the adjoining wallboard plant. 
 
 Utah Construction Company, luca Operation "" (64). The Tnca gyp- 
 sum operation of the American (4ypsnm Company and the T'^tah Con- 
 struction Company was at Inca Siding in the Little ^Maria Mountains. 
 Riverside County. Agricultural gypsum was prepareii in a plant at Tnca 
 Siding from rock gypsum quarried on the Carbutt and Orcutt property 
 and shipi>ed primarily to the Fresno area in the San Joaquin Valley. 
 
 The darhutt and Orcutt ]iro]-)erty consists of 5 patented claims. Stand- 
 ard ({v])sum and Standard (J\psuni numbers 2 through o, in sees. 2, 10, 
 and li, T. 4 S., 20 E.. SB:\r. these claims were patented before 1919 by 
 the Standard Gypsum Company, but no production was made at this 
 time other than the shi)i]iiiig of ])ulk samples to Los Angeles for calcining 
 tests. F. A. (iarbutt ami W. W. Orcutt acquired the projierty in 1920; 
 it is now owned by the Orcutt estate. In 1945 the Gypsum Products 
 Corporation of San Francisco leased the property and carried out an 
 extensive exjiloration jirogram. Tn the most recent ojieration the deposit 
 was leased by th(> American Gypsum Company of Fresno who engaged 
 the Utah Construction Company to do the work. In 1948 the Utah Con- 
 struction Company ac(|uired an interest in the enterpri.se. AVork began 
 in September 1946 and continued intermittently until June 80, 1950 
 when the operation was abandone<l, and the lease was terminated. During 
 this period about 60,000 tons of agricultural gypsum was mined and 
 shipped. 
 
 Inca, a siding on the Rii)ley brancli of tlie Santa Fe railroad, is 20 
 miles northwest of Plythe and 1\ miles from tlie Blythe-^Midland road. 
 There is no water supply in the vicinity, and that used in the operation 
 was brought in tank cars from Blythe. Electric power is not available. 
 There are no living accommodations at Inca, and most of the men em- 
 ployed there lived at Blythe. 
 
 The geology of the Little Maria IMountains gypsum deposits is dis- 
 cussed in detail in an earlier section of this report. ^lo.st of the gypsum 
 came from a low hill composed of lenticular gyjisum bodies 10 to 20 feet 
 thick that diji about 60°. The gypsum is interbedded with green felds- 
 pathic quartzite and schist and a minor proportion of tremolitic lime- 
 stone. Late in the life of the operation a second quarry was opened in 
 one of the gypsum zones which consist of gypsum interbedded with 
 limestone. 
 
 Most of the following data apply to the main quarry. 
 
 Most of the exploration was carried out by the previous operator, the 
 Gypsum Products Corporation. In addition to opening the deposit with 
 test pits and trenches, it was explored by 23 diamond drill holes totaling 
 
 101 Plant visit March 1949. 
 
106 GYPSUM IN CALIFORNIA [BuU. 163 
 
 over 3800 feet. The longest hole was 416 feet. Core recovery averaged 
 over 98 percent. 
 
 The gypsum body contained a comparatively small amonnt of inter- 
 bedded Avaste, and the broken ore average 00 percent gypsum. Stripping 
 of the overburden of green-eolorcd .schistose rocks "vvas necessary how- 
 ever ; and it was accomplished with the same equipment used to remove 
 the gypsum. The waste to ore ratio was 1^ to 1. 
 
 Blast holes Avere made with an Ingersoll Rand number 71 wagon drill. 
 Using l]-inch steel, holes were drilled to a maximum depth of 20 feet 
 with 5-foot changes of steel. Holes were started with a diameter of 3 
 inches, and the diameter at the bottom was 2-|- inches. In waste, which had 
 a hardness of 41, a bit required resharpening after 20 feet, but in gypsum 
 a bit was dulled only after about 500 feet of drilling. An average of 
 240 feet per drill shift was maintained in gypsum. 
 
 At the start of operations a standard round had been devised, but 
 because of the irregularity of the deposit it was found to be impractical. 
 Generally the number of holes was based on the appearance of the face 
 and was modified as drilling progressed. Because of the great difference 
 in hardness between ore and waste the drill runner could readily tell 
 when the bit passed from one to the other. Hole depth ranged from 12 to 
 20 feet. In waste, holes were spaced on 8-foot centers. In gypsum, how- 
 ever, the hole spacing was limited to 5 feet because with a greater spacing 
 the broken rock contained too high a proportion of fragments that would 
 not pass through the primary crusher. 
 
 Holes w'ere loaded with Atlas Amodyn 40 percent dynamite and deto- 
 nated w4th Rockmaster electric caps. Zero to 4-delay caps were employed. 
 The caps were connected to the crushing plant power supply or, if that 
 were not available, were set off with a blasting machine. The average 
 consumption of explosive was 0.3 pound per ton of gypsum broken. In 
 an attempt to obtain better fragmentation, up to 1^ pounds of explosive 
 per ton of gypsum were tried, but there was no appreciable improvement. 
 
 Two Gardner Denver 055 jack hammers were available for blockholing 
 large boulders. Forty percent dynamite was used and detonated with 
 fuse and number 6 caps. But a minor proportion of the total explosive 
 consumed was for blockholing. 
 
 After blasting, a Xortlnvest number 6 shovel of 1^ cubic yards capacity 
 loaded the broken rock into an 8-cubie-yard truck. AVaste was hauled to 
 nearby dumps and gypsum to the crushing plant which was at the quarr3\ 
 Experience indicated, however, that with the comparatively small crusher 
 installed, a f-cubic-yard shovel would have been more efficient. 
 
 Gypsum was dumped from the 8-cubic-yard truck onto an inclined 
 grizzly with 2-inch openings. A 36-inch Austin-AVestern pan feeder fed 
 the grizzly oversize to the primary crusher, a 24x36-inch Austin- Western 
 jaw crusher driven by a D-l 3,000 Caterpillar diesel engine. During the 
 life of the operation wear of the crusher was negligible. 
 
 The crusher product and grizzly undersize were carried by a belt 
 conveyor to a stockpile. Gypsum was reclaimed by means of a draw point 
 in a timbered tunnel beneath the stock pile that discharged onto a second 
 conveyor belt. This belt in turn discharged into a 20-cubic-yard truck 
 for the 7-mile haul to Im'a Siding. A generator driven by a UD 18 
 International engine supplied power for the reciprocal feeder and the belt 
 conveyors. 
 
Part 2 
 
 .\IlMNti, I'KOCES.SING, AND MAKKKTINO 
 
 107 
 
 THE INCA GRINDING PLANT 
 
 Stock Pile 
 
 Picking Belt 
 
 Tyler Hummer screen 
 
 woste 
 
 + 10 mesh 
 
 -10 mesh 
 
 jeffry hommer mill 
 
 Coarse bin 
 
 Roymond Seporafor 
 
 50 mesh 
 
 1 
 
 Bulk shipments 
 (I007o minus 10 mesh) 
 (Qpprox.) 
 
 -50 mesh 
 
 Gruenler hammer mill 
 
 Fine bin 
 
 St Regis bagger 
 
 T 
 
 Sacked gypsum 
 
 (100% minus 50 mesh) 
 (approx.) 
 
 Fkji'hk 1 1. Flow sheet of the gyp.sum grinding i)lant at Inca Siding. 
 
108 GYPSUM IN CALIFORNIA [Bull. 163 
 
 A stock pile of crushed gypsum built up over a timbered tunnel was 
 
 maintained at Inea Siding. The screen analysis of the crushed gypsum 
 
 was as follows : 
 
 li-2 inches 13 percent 
 
 1-li inches 8 percent 
 
 ^-1 inch 12 percent 
 
 plus 10 mesh, minus i inch 5 percent 
 
 minus 10 nipsh 62 percent 
 
 Total 100 percent 
 
 A belt conveyor from a draw point beneath the stock pile delivered 
 the crushed gypsum to a 4- x 10-foot Tyler hummer screen having two 
 segments. Provision was made for hand picking of waste from this 
 belt. Plus 10-mesli material was separated by the screen and ground 
 in a Jeffry 48-inch hammer mill. The hammer mill product and screen 
 undersize then went to the coarse bin. This material, which was 100 
 percent minus 10 mesh and about 50 percent minus 50 mesh, was shipped 
 in bulk. 
 
 Sacked gypsum was prepared by regrinding the coarse gypsum. A 
 Raymond air separator of 30 tons per hour capacity divided it into a' 
 minus 50-mesh fraction that went to the fine gypsum bin and a plus 
 50-mesh fraction that was reground in a (iruenler hammer mill. The gyp- 
 sum was sacked with a St. Regis machine. The size of the sacked gypsum 
 was 100 percent minus 50 mesh and 82 percent minus 100 mesh. Capacity 
 of the plant was 50 tous per hour of coarse (bulk) gypsum or 7 tons 
 per hour of sacked gypsum. Both products were guaranteed to contain 
 93 percent gypsum. Power for the grinding plant was supplied by a 240- 
 kilowatt GMC diesel electric plant. 
 
 The cost of mining averaged about $1.50 a ton. Grinding of bulk 
 gypsum cost someAvhat less than $1.50 a ton. Sacked gypsum, however, 
 cost $6.00 a ton including the cost of mining. The freight rate to Fresno 
 rose from $3.40 a ton in 1947 to $5.00 a ton in January 1951. The average 
 rate during the life of the operation Avas about $4.00 a ton. 
 
 Five to 22 men were employed depending on tlie rate of operation, 
 and of these five were employed at the grinding plant. There were in 
 addition a superintendent in charge of the entire operation and a book- 
 keeper. These men Avorked one 8-hour shift a day Avhicli Avas occasionally 
 extended to up to 4 hours overtime. 
 
 Westvaco Si/nthefic Gi/p.^^ou PJnnt.'^^- Synthetic gypsum is a byprod- 
 uct of several chemical processes. ]\Iuch of the synthetic gypsum produced 
 in the United States is manufactured in connection AA'ith the phosphate 
 industry, but there are no such plants in California. The California ma- 
 terial is a byproduct of magnesia produced from salt AA'orks bittern that 
 is made at the NeAvark plant of the WestA'aco Chemical Division, Food 
 Machinery and Chemical Corporation. 
 
 At the NcAA^ark plant bittern, Avhich is obtained from the neighboring 
 solar salt AA-orks of the Leslie Salt Company, has the folloA\'ing compo- 
 sition : ^"'■''' 
 
 i'>2 Seaton, M. Y., Production and propertie.s of the commercial magnesias : Am. Inst. Min. 
 
 Met. Eng., Tech. Publ. no. 1496, pp. 12-1.5, 1942. 
 Davis, F. F., Mines and mineral resources of Alameda County, California: California 
 
 Jour. Mines and Geology, vol. 46, pp. 299, 300, 1950. 
 '»» Seaton, op. cit., p. 12. 
 
Part 2 I Mixixn, processint.. and ^marketing 109 
 
 Percent 
 
 Sodium chloride 12.5 to Kl.O 
 
 MaKiK'-^^i'i'ii chloride 6.0 to S.7 
 
 Magnesium sulfate 4.2 to (5.1 
 
 Pota.ssium chloride 1.4 to 1.9 
 
 Magiu'sium bromide 0.14 to 0.20 
 
 Because the supply of bittern is .seasonal, storage capacity larj^c enough 
 to hold a year's supply is provided. The recovery of bromine by a modified 
 Kubierschky process is the first step in the treatment of the bittern, but 
 this step does not influence the main operation, and bromine need not 
 be removed. 
 
 In the main reaction magnesium hydroxide is precipitated with cal- 
 cined dolomite : 
 
 MgCl2 + CafOino + Mg(OTI) o -> 2Mg(OH)2 + CaCl^ 
 
 calcined dolomite 
 
 In order to prevent contamination of the magnesium hydroxide with 
 gypsum sulfate must be removed before the main reaction. Tliis is ac- 
 complislied by treating the bittern with the calcium chloride produced 
 in the main reaction. 
 
 MgS04 + CaCl. + 2ir,.0 -^ CaS04 • 2H2O + MgClo 
 
 The gypsum, wliich is recovered by filtration and dried, is a fine grained 
 product of high purity. Most of it is used in tlie San Francisco Bay area 
 as Portland cement retarder and for agricultural purposes. 
 
APPENDIX 
 
CONTENTS 
 
 Page 
 Hihlio-raphy 113 
 
 Gypsiiin iiroductiou in California ., 68 
 
 Gypsum production by counties 69 
 
 Tabulated list of California sypsum deposits 120 
 
 Tabulated list of pi-oduoers aud owners 131 
 
 (112) 
 
Appendix] bibliography 113 
 
 APPENDIX 
 
 BIBLIOGRAPHY 
 
 Physical Chemistry 
 
 Bowles. Oliver. mimI Fiiniswortli. Mario. IMiysifal chcinistry of calfiiiin sulphates 
 and Kypsuiii reserves: Kcoii. (Icnlo^y, \nl. liO, pi>. 7.">S-74r>, l!tl2.>. 
 
 Farnsworth, Marie, Effects of temperature and pressure on gypsum and anhydrite: 
 U. S. Bur. Mines Rept. Inv. 20."4, .*? pp.. 1!»24. 
 
 Kelley, K. K.. Southard. J. ('., and Anderson. C. T., Thermodynamic properties of 
 frypsum and its dehydration products: U. S. Bureau of Mines Tech. Paper 02."!, 73 pp., 
 1!)41. 
 
 Posnijak, E., The system — CaSOrHsO : Am. Jour. Sci., 5th ser., vol. 35-A, pp. 1'47- 
 272. 11«8. 
 
 Ramsdell, L. S.. and Partrid;re, K. I'.. The crystal forms of calcium sulphate : Am. 
 Mineralogist, vol. 14. no. 2. pp. r)0-74. I!l2!t. 
 
 Riddell, W. C, Physical properties of calcined gypsum : Rock Products, vol. .").".. no. 
 n, pp. 68-71, 102, May 1 !).".(). 
 
 Origin 
 
 Branson. E. B., Origin of the red heds of western Wyoming: Ge(d. Soc. America 
 Bull., v.d. 20. pp. 217-230. lOlo. 
 
 Bran.son. E. B., Origin of the thick gypsum and salt deposits: Geol. Soc. America 
 Bull., vol. 20. pp. 231-242. 101.'.. 
 
 ('larke. F. W.. Saline residues, in The data of geochemestry : U. S. Geol. Survey Bull. 
 770. lip. 218-2(iO. 1!)24. 
 
 Gral)au, A. W.. Principles of salt deposition, 1st. ed., New York, McGraw-Hill Book 
 Co., 43.") pp.. 1020. 
 
 Hanks. II. (}.. On the occurrence of hanksite in California: Am. .Toiir. Sci., 3d. 
 series, vol. 37, p. (><>. ISNO (.mhydrite at Searles Lake). 
 
 Jones, J. C. The origin of the anhydrite at the Ludwig mine, Lyon County, Nevada : 
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 Jones, J. C., and Stone, R. W.. Nevada, in Stone, R. W., and others. Gypsum deposits 
 of the T'nited States: V. S. Geol. Survey, Bull. 607. Pi). 156, 157. 1020 (Gyp.sum- 
 anhydrite jirohlem). 
 
 Newland. D. H.. Relation of gypsum suiiplies to mining: Am. Inst. Min. Eng. 
 Trans., vol. (Mi. ])p. SO-OS, 11)22 (gypsum-anhydrite iirol)lem I . 
 
 Newland, D. II., The gypsum resources and gypsum industry of New York: New 
 York State Mus.. P.ull. no. 2S.3. 1020 (gyi>suin-anh.vdrite |)rol)lem). 
 
 Posnjak. E.. Depositi(Ui of calcium sulfate from sea water: Am. Jour. Sci., vol. 238, 
 pp. 559-568. 1040. 
 
 Rogers, A. F.. Notes on the occurrence of anhydrite in the United States : Columbia 
 School of Mines Quarterly, vol. .36. pp. 123-142.1015. 
 
 Rogers, A. F.. The occurrence of gyi)sum and anhydrite at the Ludwig mine. Lyon 
 County, Nevada : Econ. Geology, vol. 7, pp. 185-lSO, 1012 (gypsum-anh.vdrite problem) . 
 
 Wilder. F. A., Some conclusions in regard to the origin of gyp.sum : Geol. Soc. 
 America Bull., vol. 32. pp. 38.5.304, 1021. 
 
 Wilder. F. A., Gypsum and anhydrite : Am. Mineralogist, vol. 13, no. 0, pp. 476-480, 
 1928 (gypsum-anhydrite problem). 
 
 Geologic Reports 
 
 Anderson. Robert, and Pack. R. W.. Geology and oil resources of the west border i>f 
 San Joaquin Valley north of Coalinga. California : U. S. Ge<d. Survey Bull. 603. i»p. 
 210-212. 1015 (gypsiferous formati<ms in Merced County). 
 
 Arnold, Ralph, and .Johnson, H. R.. Preliminary report on the Midway-Sunset oil 
 region. Kern and San Luis Obispo Counties, California : T^. S. Geol. Survey Bull. 406, 
 p. 80. 1010 (gyi)site and gypsiferous formations at McKittrick). 
 
 Eldridge. G. IL. and Arnold. R.ilph, The Santa Clara Valley. Puente Hills, and 
 Los Angeles oil districts. California : V. S. Geol. Survey Bull. 309, p. 42, 1907 (gypsi- 
 ferous formations on Sulphur Mountain). 
 
 English, W. A., Geology and oil prospects of Cuyama Valley, California : T'. S. Geol. 
 Survey Bull. 621. pp. 101-215, 1916. 
 
 Fairbanks. H. W.. The geology of Point Sal : Univ. California, Dept. Geol. Sci. Bull.. 
 vol. 2, pp. 1-92, 1902. 
 
114 GYPSUM IN CALIFORNIA [BuU. 163 
 
 F;iiih:iiiks, H. W., (lypsuin in ( ":ilit'(irni;i. in Adunis, (J. I., and others, (lyiisiun de- 
 posits in the I'uited States: W S. (leol. Survey I'.ull. 22:!. pi). 119-124. 11K)4. 
 
 Gale, H. S., Avawatz salt, f;yi»*iii»>, celestite, and talc deposits, San Bernardino 
 County, California : Unpublished manuscript, 37 pp., Dec. 1!)47. 
 
 Gale. H. S.. Borate deposits in Ventura County, California : V. S. Geol. Survey Bull. 
 540, pp. 440. 447. 11)12 (syi)sinn at the Russell borax mine). 
 
 Gale, H. S.. Geology of the saline deposits of Bristol Dry Lake. San Bernardino 
 County, California : California Div. Mines special Rept. 13, 21 i)p., 1!).")1. 
 
 Grafton, L. C, The occurrence of copper in Shasta County, California : U. S. Geol. 
 Survey Bull. 430, p. 100, 1010 (occurrence of hydrothermal calcium sulfate). 
 
 Harder. E. C The gypsum deposits of the Palen Mountains. Riverside County, 
 California: V. S. Geol. Survey Bull. 430. pp. 407-41(), 1010. 
 
 Heikilla, 11. II., and .MacLt'od, G. .M.. (Je(»lot;y of the Bitterwater Creek area, Kern 
 County, California: California Div. Mines Special Rept. 6, 21 pp., 1951 (bedrock at 
 the Packwood Can.von j;,vi)site deposit). 
 
 Hess. F. L., A reconnaissance of the .yypsuni deposits of California : I'. S. Geol. Sur- 
 vey, Bull. 413, 37 pp.. 1010. 
 
 Hess, F. L., Gypsum deposit near Cane Sprinf;s, Kern County, California : U. S. 
 Geol. Survey Bull". 430. pp. 417, 418, 1910 ( Koehn Lake deposit). 
 
 Hess, F. L.. California, in Stone. R. W.. and others. Gypsum dejiosits of the United 
 States: U. S. Geol. Survey Bull. (!07. pp. r,S-,S(;. 1020. 
 
 Hobson. .1. P... The Santa Maria River: California .Min. P.ur. Rei.t. 10, p. GOl, 1890 
 (section through the Point Sal mine). 
 
 Hoppin, R. A., The geolojty of the Palen Mountains j;ypsum deposit. Riverside 
 County. California : Division of the (Jeoloiiical Sciences. C;iliforiiia Institute of 
 Technology. Coiitril)uti()n no. r)80, .Tune 10.")1 (unpublished). 
 
 Kew. A\'. S. W., (ieolo.uy and oil resources of a part of l.os Auj;eles and Ventura 
 Counties, California: U. S. (Jeol. Survey Bull. 7r>3. p. 01, 1024 (Fillmore deposit). 
 
 Miller, W. J., (Jeology of Palm Sininj;s-Blythe strip, Riverside County, California : 
 California Div. Mines Rept. 40. pp. 25-28. 1944 (Maria formation). 
 
 Moore. P.. X.. (Jypsum. in Hewitt, D. F., and others. Mineral resources in the 
 region around Boulder Dam: U. S. Geol. Survey Bull. 871. pp. ItUi, 1(57. 1936. 
 
 Moore, B. N.. Some strontium dei»osits of .southeastern California and western 
 Arizona : Am. Inst. Min. Met. Eng. Trans., vol. 115, pp. 356-377, 1935 (Avawatz 
 Mountains and Fish Creek Mountains gypsum deposits). 
 
 Moyer, T. F.. (Jypsum and anhydrite : U. S. P.ur. Mines Inf. Circ. 7049, 45 pp.. 1939. 
 
 Murdoch, .Toseiih. and Wei)l). R. W.. Minerals of California : California Div. Mines 
 Bull. 136, 1948 (anhydrite p. 49; gypsum pp. 165, 166). 
 
 Noble, L. F., and others. Nitrate deposits in the Amargosa region, southeastern 
 California: U. S. Geol. Survey Bull. 724. pp. 83, 84. 1922 (China Ranch gypsum 
 deposit ) . 
 
 Noble, L. F., Nitrate deposits in southeastern California, with notes on deposits in 
 southeastern Arizona and southwestern New Me.xico : U. S. Geol. Survey Bull. 820, 
 1931 (pp. 17-19: gypsiferous beds near Owl Spring: pp. 49-51 : Riverside Mountains 
 deposit; pp. 57-58: gypsum in Danby Lake and Cadiz Lake). 
 
 Payne, M. B.. Type Moreno formation and overlying Eocene strata on the west 
 side of the San Joaqiiin Valley. Fresno and Merced Counties. California : California 
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 gypsite deposits). 
 
 Phalen, W. C, Celestite deposits in California and Arizona : U. S. Geol. Survey 
 Bull. 540. pp. 526-531. 1912 (Avawatz Mountains deposit). 
 
 Simpson. E. C Geology and mineral deposits of the Elizabeth Lake quadrangle, 
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 Storms, W. H., San Bernardino County : California Min. Bur. Rept. 11. pp. 345-348, 
 1892 (occurrence of gypsum in the Calico borax district). 
 
 Surr, Gordon, Gypsum in the Maria Mountains of California : Mining World, vol. 34, 
 pp. 7S7-790. Apr. 15. 1911. 
 
 Watts. AV. L., The gas and petroleum yielding formations of the central valley of 
 California: California Min. Bur. Bull. 3, pp. 63, 64, 1894 (Coalinga gypsum mine). 
 
 History of Operations 
 
 California Min. Bur. California minerals : California Min. Bur. Rept. 4, p. 227, 
 1884 (gypsum operations) . 
 
 Grimsley, G. P., The g.vpsum and cement plaster industry in California : Eng. and 
 Min. Jour., vol. 71, no. 23, p. 624, June 8, 1901. 
 
Appendix] uiBLiociRAiMiY 115 
 
 l..ittii. ]\ v., r.l.ick }:<>I<1 in the .T<.;K|uin, ('.ildw.ll. Id.ili... Cixton riiiilcis. )>. 14(>, 
 l!)4'.l ( l^iircka (J.vpsimi mines, ConlinK-i ) • 
 
 Siintni\«'rs. R. .M., iJcvclopint'nt of the <;.vpsuni indnsdv ii\ st.iti-s : 1'. S. I!nr. 
 .Mines Inf. Circ. (517:!. i.i>. C '.I. l'.l-_".» ( ( '.ilifmnia ). 
 
 Division of Mines Reports 
 (Iciimil Sii III iitiirirs 
 
 Hnulley. W. W.. (Jypsum : (^ilifornia Min. liur. Rcpt. 21. pp. 261, 262. 11)2".. 
 
 Xewni.iii. .M. .v., I{<'\ icw iif niininjr for 1!)22: ('.(liforniji Min. Rnr. R<'i)t. lU. p. ."'.l. 
 1!»2:{. 
 
 Xcwniiin. .M. .V., Non-niotallic niiiifi-als of sonthern California: California Min. 
 r.nr. Kept. IS. j.p. 2:U-2:U. 1!»22. 
 
 llaniiiton, K. .McN.. A review of mining; in (\ilifornia during 1!)21 : California Min. 
 r.ur. I'nliin. Rept. no. S, j.. CO. I!t22. 
 
 Califonii:i .Min. I'.nr.. (iypsnni, in strnctnral ;iud industrial injitcri.-ils of California: 
 California .Min. I'.nr. I'.nli. .SS, pp. 2S1-2SS, IMOC. 
 
 California Min. I'.nr., Cypsum : California .Min. Rept. i:?, pp. r.();{, .".04. 1S!K>. 
 
 California Min. Rur.. Uypsuiu : California Min. Riir. Rept. 12, pp. 32:i-:52r», 1894. 
 Alfiinedd Count ii 
 
 Davis, F. F., Mines and mineral resources of Alameda Connly, California : Cali- 
 fornia Jour. Mines and Geology, vol. 46, pp. 2!H), .'iOO. 11»."() (synthetic). 
 
 California Min. I'.nr.. Alameda County: C:iIifornia Min. I'.iir. Rept. S. p. 227. ISSS. 
 
 Frexno Count if 
 
 Logan, C. A.. Rraun, I.. T., ;ind A'einon. .T. W., Mines and mineral re.sources of 
 Fresno County. California : California .lour. .Mines .•md (Jeology. vol. 47. pp. .".04-.".06, 
 l'.t.-.l. 
 I iniierini Cnuntij 
 
 Samjison. R. .1.. and Tucker. \V. I'... Mineral resources of Imperial County : Cali- 
 fornia Div. Mines Rei.t. ;W. pp. i:{4-136. 143, 1!»42. 
 
 Tucker. \V. I'>.. Imi.erial County. Calif.unia Min. Rur. Rept. 22. pp. 270-27.", 1026. 
 
 Tucker. W. B., Im|)eri;il Coimty. California .Mir.. R.ur. Rept. IK. pi). iri4. 1.".."., 1<.)2.'{. 
 
 Xewiuan. M. A.. Los Angeles Field Division — Imperial Count.v : California Alin. 
 Rur. Rept. IS. j,. 421. in22. 
 
 .Merrill. F. J. H.. The Cc.untie.s of San Diego. Imi.eri.il : California Min. Rur. Rept. 
 14. pp. 7.SS-74(». RtlC ( Imperial). 
 Inyo Count u 
 
 Xorman, I^. A.. .Tr.. and Stew.irt. R. M., Mines and mineral re.sources of In\o 
 County : Californi.i .lour. Mines ;iiid (Jeology. vol. 47. p. 12S. l!(."il. 
 
 Tucker. W. I'... Inyo County: California Min. R.ur. Rept. 17. p. 282, 1921. 
 
 lOakle, .\. S.. Iluguenin. lOmile. McLaughlin. R. R.. and >\'aring. C. A.. Alpine 
 Count.\, Inyo County. .Mo)io County : C.ilifornia ^liu. Rur. Rept. 1."., i)p. 86, S7, 1919 
 (Inyo). 
 Krrn County 
 
 Tucker. W. I... Sam|>snn. R. .1.. and (takesholt. (1. I*... .Miner.-il resources of Kern 
 Coiint.v : California .lour. .Mines and Ceology, vol. 4."., p].. 247-249, 1949. 
 
 Tucker. ^V. R.. Kern County: California Div. Mines and .Mining. Rejit. 2.".. pj.. 69, 
 70, 1929. 
 
 Tuckei-, W . R.. San I'.ernardiuo Couut,\-. Tul.ire County : California Min. Rur. 
 Rept. 1."., p. 917. 1919 (actually Keru). 
 
 Angel, Myron, Kern County : California .Min. I'.ur.. Rept. 10. p. 223, 1890. 
 Kinys County 
 
 Rradley. \V. W.. Kings C.punty : California .Min. I'.ur. Rept. 14. p. ."li7. 191(>. 
 Los A nyelex County 
 
 Tucker. W. R., Los Angeles Cotinty : California Min. I'.ur. Rept. 28, j). 327, 1927. 
 
 Rreston, F. R., Los Angeles County: California Min. R.ur. Rept. 9, p. 19."., 1SS9. 
 ]frrrei] County 
 
 Watts. W. L., Merced County : Califorui:i .Min. I'.ur. Rept. 10, p. .•'.31, 1890. 
 Orange County 
 
 liowers. Stephen. Orange County : Califr.rnia Min. R.ur. Rej.t. 10. p. 408. 1890. 
 I'ircrside County 
 
 Tucker, W. R., and Sampson, R. .L, Mineral resources of Riverside County: Cali- 
 fornia Div. Mines Rei.t. 41. pp. H.7-172. 194.".. 
 
 Tucker. W. B., and Sampson, R. ,T.. Riverside County : California Div. Mines and 
 Mining Rept. 2."., pp. .".()9-.".l."i, 1929. 
 
 Merrill, F. J. H., Riverside County : California Min. Bur. Rept. 1."j, pp. .577-579, 1919. 
 
IK) GYPSUM IN CALIFORNIA [BuU. 163 
 
 San lieniio County 
 
 Avt'iill. ('. v., Mines and niincnil resources of San Benito County, California : 
 California Jour. Mint»s and (lenlo^y, vol. 4.'-?, p. ")!, 1047. 
 
 Laizuro, C. McK, San Benito County : California .Min. Bur. liept. 22, \>. SMI 1926. 
 
 Boalieh, E. S., San Francisco field division — San Benito County : California Min. 
 Bur. Kept. 18, p. 21S, 1022. 
 
 Bradley, W. W., Huguenin, Bmile, I.K)Kan, C. A., and Waring, C. A., The Counties 
 of Monterey, San Benito, San Luis Obispo, Ventura: California Min. Bur. Rept. 15, 
 p. 639, 1919 (San Benito). 
 
 San Bernardino County 
 
 Tucker, W. B., and Sampson, R. J., San Bernardino County : California Div. 
 Mines Kept. 26, p. 307, 1930. 
 
 Tucker, W. B., San Bernardino County, Tulare County : California Min. Bur. 
 Rept. 15, pp. 869, 870, 1919 (San Bernardino). 
 
 San Diego County 
 
 Tucker, W. B., and Reed, C. H., Mineral resources of San Diego County : California 
 Div. Mines Rept. 35, p. 44, 1930. 
 
 Merrill, F. J. H., The Counties of San Diego, Imperial : California Min. Bur. Rept. 
 14, p. 6S8, 1916 (San Diego). 
 
 San Joaquin County 
 
 Laizure, C. McK, San Joaquin County : California Min. Bur. Rept. 21, p. 191, 1025. 
 
 San Luis Ohiapo County 
 
 Franke, H. A.. Mines and mineral resources of San Luis Obispo County : California 
 Div. Mines Rept. 31, p. 423, 1935. 
 Santa Barbara County 
 
 California Min. Bur., Santa Barbara County: California Min. Bur. Rept. 8, p. 538, 
 1888. 
 Ventura County 
 
 Waring, C. A., The Counties of Monterey, San Benito, San Luis Obispo, Santa 
 Bai-bara, Ventura : California Min. Bur. Rept. 15, p. 761, 1019 (Ventura). 
 
 Bowers, Stephen, Ventura County: California Min. Bur. Rept. 8, p. 688, 1888. 
 
 Mine and Plant Descriptions 
 
 Avery, W. M., National Gypsum's Baltimore plant : Pit and Quarry, vol. 42, no. 8, 
 pp. 62-67, 74, February 1950. 
 
 Chem. Engineering, Anhydrite fights Britain's sulphur shortage : Chem. Engineer- 
 ing, vol. 58, no. 7, pp. 212, 213, July 1951. 
 
 Holmes, G. H., Jr., Mining, milling, and manufacturing methods at the Blue 
 Diamond Corp.'s gypsum property, Clark County, Nevada: V. S. Bur. Mines Inf. 
 Circ. 7555, 21 pp.. 1950. 
 
 Nordberg, Bror, Manufacture of gypsum plaster and wallboard : Rock Products 
 vol. 53, no. 1, pp. 137-141, 161, 174, January 1950 (Blue Diamond plant near Arden, 
 Nevada ) . 
 
 Rock products, Newest plaster board plant on west coast : Rock I'roducts, vol. 50, 
 no. 9, pp. 74-77, Septeml)er 1947 ( Kaiser plant at Long Beach \ . 
 
 Seaton, M. Y., Production and properties of the commercial magnesias : Am. Inst. 
 Min. Met. Eng., Tech. Pub. no. 1406, p. 12, 1042 (Manufacture of synthetic gypsum 
 at Westvaco's Newark plant). 
 
 Stewart, G. E.. Billin-ham mine: Inst. Min. :Met., Bull. 480, pp. 1-11, 1046 
 (anhydrite mine in England). 
 
 This Earth, San Marcos: This Earth, vol. 3, no. 2, pp. 3-5, February 1050 (Kaiser 
 gypsum quarry on San Marcos Island). 
 
 Utley, F. H., "World's richest gypsum quarry" sui)i)lies new board plant : Pit and 
 Quarry, vol. 40, no. 3, pp. 114, 124, September 1047 ( Kai.ser plant at Long Beach). 
 
 Waldron, .J. F., New gypsum tile plant of rniversal (iypsum and Lime Company, 
 Rock Products, vol. 20, no. 26, pp. 143-147, December 25, 1926. 
 
 Gypsum Dust 
 
 Forbes, J. J., Davenport, S. J., and Morgis, G. G., Review of literature on dusts : 
 U. S. Bur. :\Iines Bull. 478, pp. 238-242. 1050. 
 
 Rock Products, E.xperience of gypsum products manufacturers : Rock Products, vol. 
 27. no. 13, pp. 31-33, June 29, 1924. 
 
Appendix] bibliography 117 
 
 Beneficiation 
 
 Kf'ck. W". 10.. .ind .IjisIxt;:. Paul. A Stinly of tin' flnt.itivc properties of pypsuni : 
 Am. lust. .Mill. .Met. Kuii. Traii.s.. vol. ll.'!». pp. 21S 1>:U. VX\S. 
 
 I'rater, L. S., Kenpficiiition tests on K.vpsuui rock from Wasliiii;;toTi County, Idaho: 
 Idaho liur. Mines and (Jeolojiy. Paniph. 77, <5 pp.. 1M47. 
 
 Rock Products. Plant oper.itiuns geared for lowered unit cost: Rock Products, vol. 
 ."i.'{, no. lli. 1). !•(>, December IK.'iO (washinjr of crude K.vpsum is practiced in Nova 
 Scotia I . 
 
 Gypsum Industry — General 
 
 Coll'. 1,. II.. The CvitsMiii industry of Canada: Canada I)e|)t. of Mines, Mines 
 Hranch, no. 714. lt'>4 pp.. I'.i.'UI ( occurrfiicc. i)rf|>:nalinii, .-md uses of >:ypsum). 
 
 Cole, L. II., and Ko;:ers. K. A.. Anhydrite in Canada : Canada l>ept. of Mines, Mines 
 Hranch, no. TA'2. S!) pp., lU.S.'i (occurrence and u.ses of anhydrite). 
 
 Eckel. E. C., Cements, limes, and plasters. 2nd. ed.. pj). IS-IM). Xew York. John 
 Wiley .and Sons, Inc.. I'.l'Ji* (mining, preparation, and uses of ;;ypsum). 
 
 Gypsum in Agriculture 
 
 California Ai^v. Exp. Station. The use of lime and gypsum on California soils: 
 Californi.i A^-r. Exp. Station. Ciic. Ill, 1021. 
 
 California A«;r. Exp. Station. Keclaniation of the Fresno type of black-alkali .soil : 
 Californi.i A>;r. Exp. Station. Hull. 4r>.-.. 1!»1>S. 
 
 Calif(u-nia A;;r. Extension Service and t'ounty of Kern, Methods of applyiii}; K.vpsum 
 to irrifiation water: California Agr. Extension Service and County of Kern, joint 
 publication, no number. .lanuary 104(5. 
 
 California Agr. Extension Service and County of Kern, Progress report on water 
 jienetration studies in Kern County: California Agr. Extension Service and County 
 of Kern, joint publication, no number, July 1047. 
 
 Colby. (J. E.. A note on the u.se of anhydrite as a remedy for black alkali : California 
 Dept. .U'ricnlture. P.ull. 10. no. 1. i)p. SO-41. 1021. 
 
 Cornell Agr. Exp. Station. Calcium sulfate as a .soil amendment; Xew York, 
 Cornell Agr. Exp. Station. Mem. 07, 102(!. 
 
 Hibbard, 1'. L., Alk.ili soils : origin, examination, and management : California Agr. 
 Exp. Station, Circ. 202, 1087. 
 
 Iowa Agr. Exp. Station, Field experiments with gyi)sum in Iowa : Iowa Agr. Exp. 
 Station. P.ull. 2;i2. 102.1. 
 
 Kellfv. W. P.. The reclamation of alkali soils: California Agr. Exp. Station, Bull. 
 til7, io:;7. 
 
 Mctieorge, W. T., (Jypsiim. a soil corrective and soil builder: Agr. Exp. Station, 
 I'niv. of Ariz..n.i. Hull. 200. 14 pp.. 104.".. 
 
 New Mexico Agr. Exp. Station. The value of agricultural gypsum: New Mexico 
 Agr. Exp. St;ition, Press Hull. .".4.S. 102S. 
 
 R<dlins, R. Z., Agricultural gypsum, in Minerals for the .soil : California I)iv. Mines 
 Hull. 1."..".. pp. lO.-.-lKi, lO.'.l. 
 
 Scott, F. T., rnpublislied iiajx'!- (lelivere<I .at California Fertilizer Association, 
 Nov. 7-!>, 3 i)p., 1040 (use of gypsite in the San Joaquin Valley). 
 
 Washington Agr. Exp. Station. (Jypsum (land plaster) for peas: Washington Agr. 
 Exp. Station, Circ. 17, 1044. 
 
 Portland Cement Retarder 
 
 Houge, R. II., The chemistry of j)ortland cement, pp. 472-487, New York, Reinhold 
 Publishing Corp. 1047 (function of gypsum in the setting of portland cement). 
 
 Hansen, W. C, and Hunt, J. O., The use of natural anhydrite in portland cement : 
 A. S. T. M., Hull. no. 1(51, pp. .".()-.", October 1040. 
 
 Roller, P. S., and Halwer. Murray. Relative value of gypsum and anhydrite as addi- 
 tions to Portland cement : V . S. Hur. Mines Tech. Paper 57.S, 1") pp., 10.37. 
 
 Rutle, Jobs, Effect of gyp.sum content on cinnpressive strength of cements : Pit and 
 Quarry, vol. 4.S, no. 1, pp. 87, 88, 07, July 10.^>0. 
 
 Slegten, J. A., What cau.ses defective concrete?: Rock Products, vol. ."il. no. 10, pp 
 05, 112, Oct. 1048 (relations between the gypsum content and strength of concrete). 
 
 Witt, J. C, I'ortland cement technology, pp. 117, 118, Brooklyn, Chemical Publish- 
 ing Co., 1947 (use of gypsum as a retarder). 
 
118 GYPSUM IN CALIFORNIA [BuU. 163 
 
 Plaster Manufacture 
 
 Host, J. C, Kt't'iie's i-enient : its uses :iik1 manufacture : Rock I'roclucts, vol. 34, no. 
 26, pp. 47, 48, December 19, 19.31. 
 
 Kanowitz. S. B., and others, Crushinj;. j^rindin};, and other methods of comminution, 
 in Chemical enf^ineers' handliook, 2d. ed., pp. l.SS.~)-2()()7, New York, Mc(Jraw-Hill 
 Book Co., 1941. 
 
 McAnally, S. G., (Jyiisnm and };ypsuin products manufacture : Rock Products, vol. 33, 
 no. 14, pp. 70-73. no. 17. pp. 0(v69, no. 19, pp. (58-70, no. 21, pp. 40-48, no. 23, pp. 53-55, 
 no. 25, pp. 40, 47, 1930. vol. 34. no. 4, pp. 37-39, no. 0, i)p. 50-58, no. 8. pp. 47-49, 
 no. 12, pp. 0f)-07, no. 15. pp. 54-50. 19.''.1. 
 
 Pit and Quarry I*ul)lications, (Jyjjsuin ]>lant design, in I'it and quarry handhoolc, 
 44th ed., pp. 41-40, Chicajco. Complete Service I'ublishins Company, 1951. 
 
 Rock Products, Commercial manufacture of gvpsum retarder : Rock Products, vol. 
 29, no. 20. pp. 147-149. Dec. 25. 1920. 
 
 St. Clair, O. A., <iyi).suni plant desij;n. in Pit and quarry handbook, 39th ed., pp. 
 39-45, Chicajio, Complete Service Pul)lishin},' Co., 1940. 
 
 Turner, A. M., The manufacture of gypsum plasters : Rock Products, vol. 33, no. 10, 
 pp. 52, 53, no. 18, pp. 55-57, no. 22, pp. 39-42, no. 22, pp. 49-51, no. 24, pp. (52-04, 19.30. 
 
 Gypsum for Building 
 
 A. S. T. M. standards. Part III. cement, concrete, ceramics, thermal insulation road 
 materials, waterprooiing, soils, Philadelphia. American Society for Testing Materials, 
 1949. 
 
 G.vpsum lath : (Jypsum Association. A. I. A. file no. 2n-B-2. 
 
 Gypsum lathing and plastering, (iypsum Association, .37 pp., 1949. 
 
 Gypsum partition tile and fireproofing : Gypsum Association, A. I. A. file no. 10a3, 
 21 pp. 
 
 Gypsum sheathing : (Jypsum Associ.-ition. A. I. A. tile no. 19D-3. 7 pp. 
 
 Gypsum walll)oard : (Jypsiim Association. A. I. A. tile no. 23-1^. 15 pp. 
 
 Sound al)sorbing gypsum plaster : (;yi)sum Association, A. I. A. file no. 39-B. 
 
 Schweim, H. .7.. Reinforced gypsum concrete building code requirements approved as 
 American standard : reprint from Industrial standardization. 8 ])]).. .Tuly 1941. 
 
 Industrial Piasters 
 
 Classon. C. K.. Evolution and use of gypsum cement for oil wells: World Oil, vol. 
 129, no. 4, pp. 119-12(5, August 1949. 
 
 Eberl, .1. .7., and Ingram, A. R.. Process for making high-strength jtlaster of Paris : 
 Ind. and Eng. Chem., vol. 41. pp. 1001-10()5. 1949. 
 
 Hedvall. ,T. A.. Sandford, F.. and Ahlberg. R., Method for regeneration of plaster of 
 Paris: Am. Ceramic Society .Tour., vol. .30. no. 11, pt. 1, pp. 323-329. 1947. 
 
 Touchman. S. X.. Pressure casting aluminum matchplates in plaster molds: 
 Foundry, vol. 70, no. 7. pji. 7(5-78. 194, 198, July 1948 ( use of gypsum in foundry 
 practice) . 
 
 Wiss. J. E., Recent developments in tlie use of gypsum pl:isters in ceramics : Pacific 
 Coast Ceramic News, vol. 1, no. 10, pp. 13, 17, April 1951 and no. 11, p. 14. May 1951. 
 
 Economics 
 
 Arundale. .7. C. and Downey. M. G.. Gyi)sum : T\ S. Bur. Mines Minerals Yearbook, 
 11 p])., 1949 (preprint). 
 
 California Bur. Chemistry. Fertilizing materials. 1947-1949: California Dept. Agri- 
 culture, Special I'ubs. no. 227, 231, 230 (agricultural gypsum statistics, registrants, 
 analy.se.s) . 
 
 Mining World. \-ol. 11. no. 7. p. 50. .7une 1949 (announced cost of new i>lant at 
 Gerlacb, Nevada ) . 
 
 Noi'dberg, P.ror. The National Gypsum Company Story: Rock Products, vol. .53, no. 
 12, p. 88. Dec. 1950 (National (iypsum Co. activity in Imperial County). 
 
 Pit and quarry, vol. 41, no. 7, pp. 97, 98, .lanuary 1949 (announcement of V. S. 
 Gypsum Co.'s exi)ansion on the west coast). 
 
 Santmvers, R. M.. Marketing of gvpsum products : I'. S. Bur. Klines Inf. Circ. 0157, 
 29 pp., 1929. 
 
Appendix 1 tables 110 
 
 TABLES 
 
 ill llic tahlfs of this section, the following? abbroviations are used 
 Under eohunn lieaded "Class — production" : 
 
 "A." Iinlicatcs prddiiction of iinn-c tluiii l()<l.(i(l(t Ions 
 
 "B." Iii(lic:itt"s production of 10,(K)() tons to lOO.OOO tons 
 
 "C." Indicates production of less tlian 1(),(HM) tons 
 
 "I>." Indicates no production except bulk sampling 
 
 lender eolunin headed ' ' Class — geoloj^ical ' ' : 
 
 "a" indicates ;;ypsit(> deposit 
 
 "!)" indicates pla.va deposit 
 
 '"c" indicates iie<lded Tertiary deiiosit 
 
 "d" indicates lens-sliajx-d irrejjular l)od.v in shale 
 
 ''e" indicates pre-Tertiary deposit 
 
 "f" indicates <;round\vater vein (selenite and satin si)ar) deposit 
 
 "fj" indicates liydrol hernial (h'jiosit 
 
 "h" indicates synthetic product ion 
 
 Under column licadcd "References": 
 "R" refers to Report of the California State Mineralogist, "B" to a 
 bulletin of the California Division of Mines. In the references that show 
 a name followed by numbers scjiaratcd l)y a coIoil the name refers to the 
 author, as listed in the accompanyino' bibliography. Tlie first niunber is 
 the date of publication of the article, except tIio.se following "B," whicii 
 are bulletin numbers; the second number — that following the colon — is 
 the page reference. A reference given as "llcss 20:83'' would refer to 
 an article by Iless published in li)2(). The bibliography gives, under 
 "Hess, F. L., the complete data: T'^. R. Geological Survey Bull. 697, 
 published in 1920. The "83" woidd refer to page 83 of U. S. Geological 
 Survey TUilletin GOT. 
 
 Under columns headed * ' Location ' ' : 
 
 '"B and M" is an al)hre\iation for "hase and meridian" 
 "SIV refers to San I'ernardino l>ase ami meridian 
 "MD" refers to Mt. Diablo base and meridian 
 
 "Proj" (for iirojected) is used aftei- tlie location if the imhlic land surveys 
 are not complete on tlie base maii. 
 
 Under columns headed ' ' Map number ' ' : 
 Numbers listed are those shown on the accompanying map, plate 1. 
 
]20 
 
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136 
 
 GYPSUM IN CALIFORNIA 
 
 [Bull. 163 
 
 0) 
 
 3 
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 Angel 90:223 
 Hess 20:75 
 
 B38:288 
 
 Tucker and Sampson 45:168 
 
 Tucker and Sampson 29:510; 
 Tucker and Sampson 45: 
 170 
 
 E 
 
 Small production. Leased (?) to Pampa 
 Gypsum Co., Cottonwood Co., Gyp- 
 sum Mining Co. 
 
 Abandoned; operations transferred to 
 Palmdale 
 
 Sold to Acme Cement and Plaster Co. 
 No production after 1906 
 
 No production reported 
 
 Owner in 1944. Leased to Levi Katz 
 and Floyd Shoemaker 
 
 Partner with G. W. Lord after 1916. 
 Executor of Lord's estate 1918-1920. 
 Operator of the deposit after 1920 
 
 Assessment work only by Garland. 
 Sold to U. S. Gypsum Co. between 
 1930 and 1945 
 
 Owner in 1926. Claim included in 
 Regent Placer patented in 1928 by 
 Pacific Portland Cement Co., now 
 owned by U. S. Gypsum Co. 
 
 Gypsite. Deposit 4 miles southwest of 
 McKittrick 
 
 3:s 
 at 
 
 1890-1898 
 
 1904, 1905 
 
 1906-1910 
 
 About 1904 
 
 1916-1937 
 
 1941 
 
 si 
 
 o -w 
 
 c 
 
 Cottonwood Creek deposit 
 
 Charlie Canyon deposit 
 
 Palmdale 
 
 Santa Barbara Canyon de- 
 posit 
 
 Eagle Canyon deposit, Corona. 
 
 Gypsum Canyon deposit. 
 Corona 
 
 Garland deposit, Maria Moun- 
 tains 
 
 Fish Creek Mountains 
 
 Telephone Hills, McKittrick. 
 
 a 
 
 W. A. Fauntleroy 
 
 Fire Pulp Plaster Co 
 
 Fire Pulp Plaster Co 
 
 C. D. Fox 
 
 T. A. Frazer 
 
 G. R. Freeman (see also G. W. Lord) 
 
 Freeman: See E. R. Nonhofif and Free- 
 man 
 
 F. A. Garbutt and W. W. Orcutt: see 
 W. W. Orcutt estate 
 
 Garland 
 
 W. F. Gillett 
 
 W. L. Gillette: see David Chaplin and 
 W. L. Gillette 
 
 Green and Collins 
 
 1-^ 
 
 oMOOMira ooM 00 
 
 COIOU505050 OC^ ■<>' 
 
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146 
 
 GYPSUM IN CALIFORNIA 
 
 [Bull. 163 
 
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 and Sampson 29:513-515; 
 Tucker and Sampson 45: 
 170-172 
 
 Herein 
 
 CO 
 
 a 
 
 Undeveloped. Access road started 
 
 No record of production 
 
 Deposit and calcining plant bought 
 from Consolidated Pacific Cement 
 Plaster Co. Last production 1924. 
 Plant dismantled 
 
 Deposit and plant bought from Pacific 
 Portland Cement Co. Manufacturer 
 of raw and calcined gypsum prod- 
 ucts 
 
 Development and production. Pro- 
 duction began 1925. Calcining plant 
 completed 1928 
 
 Producer of high grade ground agri- 
 cultural gypsum. Mined gypsum 
 from Garbutt and Orcutt property 
 * for American Gyr)sum Co. Grinding 
 plant at Inca Siding, .\cquirod an 
 interest in the operation in 1948 
 
 Gypsite producer, class B 
 
 Gypsite producer. Leased from L. L. 
 Styles. Deposit worked by owner in 
 1951 
 
 Plant at Calexico producing agricul- 
 tural mineral containing gypsum 
 and sulfur. Gypsum reported mined 
 in 1944 
 
 
 About 1945 
 
 1942 
 
 19191 
 
 ■19451 
 
 Before 1914' 
 
 1947-1950 
 
 1939-1943 
 
 1947-1950 
 
 1944 
 
 
 -4^ 
 
 o ^ 
 ta o 
 
 H 
 
 Riverside Mountains 
 
 Panoche Hills 
 
 Bristol Lake. 
 
 Fish Creek Mountains mine.. 
 
 Plaster City plant 
 
 Midland deposits 
 
 I Ilea operation 
 
 Belridge 
 
 Shandon deposit 
 
 Coyote Mountains Sulfur and 
 gypsum deposit 
 
 a 
 
 03 
 
 Rodney Turner and Associates 
 
 Uneeda Gypsum Co., R. B. Steyer 
 
 United States Gypsum Co., 300 W. 
 Adams St., Chicago 6, Illinois 
 
 United States Gypsum Co., 300 W. 
 Adams St., Chicago 6, Illinois 
 
 United States Gypsum Co., 300 W. 
 Adams St., Chicago, Illinois 
 
 United States Gypsum Co., 300 W. 
 Adams St., Chicago 6, Illinois 
 
 Utah Construction Co 
 
 Valley Agricultural Gypsum Co 
 
 Valley View mine: see R. P. Jones 
 
 Valley View Placer: see Green and 
 Collins 
 
 C. E. Vanderford 
 
 Vesubio Mining Corp., Box 592, 
 Calexico 
 
 li 
 
 
Appendix] 
 
 TABLES 
 
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Appendix] 
 
 INDEX 
 
 149 
 
 INDEX 
 
 Acme Cement and Plaster Company, 38, 
 
 71 
 Agricultural K.vpsum, 70 
 
 Minerals and Fertilizer Co., 
 49 
 Alpine Plaster Company, 67, 70 
 American Gypsum Company, 1.'?, lOH 
 Amestoy Mineral Fertilizer Company, r»8 
 Anderson, C. T., cited, 85 
 Anhydrite, 34 
 
 , uses of, 97 
 Anhydrous plasters, 89 
 Arden, Nevada, 9 
 Avawatz Mountains, 9, 39, 43, 44 
 
 deposits, 43, 44, 6(), 
 61 
 Salt and Gvpsnm Company, 43, 
 45,46 
 Avenal Gap mine, 56 
 
 Ballinger Canyon, 35 
 Bolridfie, 72 
 Benjamin Franklin, 76 
 Big Gypsum Hill, 45 
 
 (Kelley) Hill, 45 
 Blue Diamond urea, 38 
 
 Corp., 29, 35, .37 
 Bolo Gypsum Company, 47 
 Boston Valley salt claims, 44 
 Boyer, L. F., cited, 43 
 Branson, E. B., cited, 60 
 Bristol I-ake, 47, 59 
 Brown mine, 104 
 Burges Canyon, 41 
 
 Calcium sulfate, 85 
 Caliente red beds, 35, 37 
 California Gypsum Corp.. 72 
 
 Portland Cement Company, 29 
 State Bureau of Chemistry, 
 76, 80, 82, 84 
 Department of Agricul- 
 ture, 76 
 Division of Industrial 
 Safety, 74 
 Camp Irwin. 43 
 
 Canada Department of Mines, 98 
 Carrisa mine, 58 
 Carrizo Plain, 58 
 Cave Spring Wash, 44, 45 
 Celestite, .34 
 
 Cement Plaster Company, 70 
 Certain-teed Products, ,38 
 China Ranch, 60, 71, 74 
 
 deposits, 38 
 Clark County, Nevada, 13 
 Clark Mountain area, 24 
 Colby, G. E., cited, 97 
 Colorado Indian Reservation, 24 
 Combined sulphur equivalent, 77 
 Confidence mill, 45 
 
 Consolidated Pacific Cement Plaster 
 
 Company, 70 
 Copper Canyon deposit, 39 
 Corona de]X)sits, 57 
 Corral Canyon, 35 
 Cottonwood Creek deposit, 67 
 Crown Plaster Company, 71 
 Cuddy Canyon deposit, 39, 40 
 Cuyama Valley deposits, 41, 60, 97 
 
 Danbv Lake, 48 
 
 Death Valley. .38 
 
 Denning Spring, 45 
 
 Desert Center, 21 
 
 Dibblee, T. W., Jr., 29, 60 
 
 Domengine formation, 50 
 
 Dos Palos Gypsum Company, .50 
 
 Dunne quarries, 70 
 
 Eagle Canyon, .58 
 Escondido formation, 57 
 
 Fairbanks, H. W., cited, 7 
 Fertilizing materials, 82 
 Fillmore deposit, 59 
 Fire Pulp Plaster Co., 70 
 Fish Creek Canyon, 29, 30, 31 
 
 Mountains, 29, 31. 61, 63, 97 
 deposit, 7, 8. 9, 29, 
 
 .32, .39, 71.72 
 index map, 28 
 Franklin, Benjamin, 76 
 Furnace Creek deposit. 39 
 
 Inn, 39 
 Frenchman's Point, 41, 43 
 Fresno County deposit, 49 
 Funeral fanglomerate. 44 
 
 Garlock, 46 
 
 fault, 44 
 Gerlach, Nevada, 9 
 Golden Gate Plaster Mills, 67 
 Grabau, A. W., cited. 60 
 Granite Mountains, 21, 23 
 
 (Palen) Pass, 21 
 Grimes Canyon, 59 
 Gypsite, calcination of, 88 
 
 deposits, 7 
 Gypsum Company of California, 55 
 
 calcination of, 85 
 
 (Main Street) Canyon, .58 
 
 plaster, setting of, 85 
 
 production by counties, 69 
 in California, 68 
 
 Products Corporation of San 
 Francisco, 105 
 
 , uses of, 96 
 
 Hagador Canyon, 58 
 Harder, E.C., cited, 21, 01 
 Hess, F. L., cited, 7 
 Hewett, D. F., cited, 27 
 Hoppin, R. A., cited, 21, 23 
 
150 
 
 GYPSUM IN CALIFORNIA 
 
 [Bull. 163 
 
 INDEX (cont.) 
 
 Imperial formation, 31 
 
 Gvpsum and Oil Corporation, 
 71,72 
 Inca grinding plant, 107 
 
 Jumbo deposit, 46 
 
 Jurassic (?) granitic rocks, 40 
 
 Kaihal) formation, 13, 27 
 Kaiser Gvpsum Division, Long Beach 
 
 plant, 101 
 Redwood City 
 plant, 102 
 Keene's cement, SO, 00 
 Kelley, K. K., 85 
 Kern County deposit, 51 
 Kern liake deposit, 51, 52 
 Kiii«s County deposits, 56 
 Koehii Lake dejuisit, 52, 71 
 Kreyenhagen formation, 57 
 
 Las Vegas, Nevada, 7 
 
 Leach Lake Road, 39 
 
 Lee, H. C, cited, 43 
 
 Leslie Salt Co., 108 
 
 Lewis and Johnson, 43 
 
 Little IMaria Mountains, 61, 63, 97, 104, 
 
 105 
 deposits, 8, 9, 13, 
 
 14 
 Panoche Valley deposits, 49 
 Long Beach, 72 
 
 Los Angeles County deposits, 57 
 Lost Hills deposits, 52 
 Lyons Gypsum Company, 70 
 
 Mack's cement, 90 
 Magand's cement, 90 
 Maria formation, 13, 14, 21 
 
 Mountains, 13 
 Maricopa Gypsum Company, 41 
 
 shale, 56 
 McCoy Mountains formations, 21 
 McDonald .shale, 56 
 McKittrlck, 9, 72 
 
 Agricultural Gypsum Com- 
 pany, 55, 56 
 deposits, 53 
 
 Extension Oil Company, 53 
 formation, 58 
 Merced County deposits, 57 
 Mesquite Valley, 24, 27 
 Midland deposits, 71 
 
 Ranch, 74 
 Miller, W. J., cited, 13, 14, 15, 21 
 Mint Canyon deposit, 40 
 Mineral Fertilizer Company, 58 
 Miocene, Caliente red beds, 41 
 
 ( ?) Vasques formation, 40 
 Moenkopi formation, 13, 27 
 Monolith Portland Cement Company, 
 
 35, 103 
 Monterey formation, 56 
 
 Gypsum Company, 40, 71, 103 
 
 Moore, B. N., cited, 15 
 Mule Shoe Ranch, 62, 70, 71 
 deposit, 40, 103 
 
 National Gypsum Company, 29 
 Natural Fertilizer Company, 58 
 Newland, D. H., cited, 61 
 Noble, L. F., cited, 24 
 North Limestone, 16 
 
 Ortigalita Creek, 9 
 
 Owl Hole Spring deposit, 39 
 
 Pahco Products, Inc., 103 
 
 Pacific Cement Plaster Company, 47, 70 
 Gypsum Company, 51, 52 
 Portland Cement Company, 72 
 
 Packwood Canyon deposit, 56 
 
 Palen Mountains, 9, 13, 21, 97 
 deposits, 21 
 
 Palradale deposits, 57 
 
 Pan Chemical Company, 29 
 
 Panoche Hills, 72 
 
 deposits, 50 
 
 Paoli Gypsum Company, 50 
 
 Parian cement, 89 
 
 Paso Robles formation, 40 
 
 Peeler deposit, 29 
 
 Permanente Silverbow, 101 
 
 Plaster City plant, 72 
 
 Point Sal mine, 67 
 
 Portland cement retarder, 84 
 
 Posjnak, E., cited, 23, 62 
 
 Pottery plaster, 95 
 
 Prefabricated products, 92 
 
 Quatal Canyon, 35, 63 
 
 deposit, 7, 8, 9, 35, 41, 63, 
 73 
 red clay, 37, 38 
 
 Riverside County deposits, 57 
 Mountains, 9, 24, 97 
 
 deposits, 24 
 Rogers, A. F., cited, 62 
 
 Salt Basin, 45, 46 
 
 Salton Sea, 61 
 
 Sampson, R. J., cited, 29 
 
 San Andreas fault zone, 35, 40 
 
 Luis Obispo County deposits, 58 
 Marcos Island, 7, 9, 72, 101 
 deposit, 102 
 Santa Ana Mountains, 57 
 Barbara Canyon, 41 
 Margarita formation, 35, 41 
 Rosalia, 9 
 Santiago Peak volcanics, 58 
 Shandon deposit, 58 
 Sheep Creek deposit, 46 
 Shire deposit, 27 
 
 map of, 25 
 sections through, 26 
 Skelenger mine, 105 
 Soil Tone Company, 58 
 
Appendix] 
 
 INDEX 
 
 151 
 
 split .Mminljiin forniatiun. :50, 31, .'J2, iW 
 South D.'.itli Valley road, 39, 43, 44, 45 
 
 (•rauite, It) 
 Southar.l, J. C. cited, 85 
 Standard (Ivpsuin Company, 72 
 Sunset riaster and Cement Company, 59 
 Surr, Gordon, cited, 14 
 
 Telephone Hills deposit, 55 
 
 pypsite working, 54 
 Temblor Range, 53 
 Tertiary lake beds, 44 
 Trian;,'le Fertilizer Company. 71 
 Truck load rates, 100 
 Tumey (Juk-h, 72 
 Tumey fiulcli deposits, 50, 51 
 Turritellas, 50 
 
 United States Department of Agricul- 
 ture, 09 
 Gypsum Company, 13, Ifi, 
 '27,29,31,32,33,34. 71. 
 97, 104 
 
 INDEX (cont.) 
 
 LiiiM'rsity of California Agricultural 
 
 Kxi)eriment Station, 77 
 rtah Construction Company, 13, 17, 18 
 
 Quarry, IS. 
 19, 64 
 
 Vatiucrns luruiation, 41, 51 
 Ventura County ileposits, 59 
 Victor mine, 104, 105 
 
 Wagon Road Canyon deposit, 42, 43 
 
 West End, The, 45 
 
 Western Atlas Corp., 43 
 
 Western Gypsum Company, 55 
 
 Westvaco Chemical Division, Food Ma- 
 chinery and Chemical Corpo- 
 ration, 9, 72, 108 
 Synthetic Gypsum Plant, 108 
 
 Wilder, F. A., cited, 60 
 
 printed in CALIFORNIA state printing opfice 
 
 58771 3-52 2M 
 
M 5 '8i 
 
 THIS BOOK IS DUE ON THE LAST DATE 
 STAMPED BELOW 
 
 AN INITIAL FINE OF 25 CENTS 
 
 WILL BE ASSESSED FOR FAILURE TO RETURN THIS BOOK 
 ON THE DATE DUE. THE PENALTY WILL INCREASE TO 
 50 CENTS ON THE FOURTH DAY AND TO $1.00 ON THE 
 SEVENTH DAY OVERDUE. 
 
 JAN 6 1971 
 
 JAN 8 1979 
 NOV 3oREC'D 
 
 JUN 3 1987 
 
 CFIVEL; 
 
 AUG t <J 1997 
 
 M2?^ 
 
 Physk 
 
 0^ fpc ^ 
 FID'^O 1 1996 
 
 
 JAN 1 9 2000 
 
 'REIVED 
 
 Jill '■*> 
 
 -jL^i'a/y 
 
 
 Book Slip-30m-8,'54 (621084)458 
 
* 
 
 
 
 GEOLOGY 
 
 
 
 
 
 BULLETIN 163 
 
 • 
 
 mt 
 
 
 PLATE 1 
 
 > 
 
 ' 
 
 ^ GYPSUM 
 
 DEPOSITS 
 
 
 
 
 ). Mhiiim liiii ItiiUe ili|io-it 
 
 Inyo County 
 
 6i. CarliuM and Orrult deposit 
 
 
 ■ 
 
 .. Miiiiorline Kiittt ik'posll 
 
 30. Black MDuntalii-. di-po-iit 
 
 65. Cypsum (Main Strt-el) Canxon 
 
 
 
 . rimll mine 
 
 31. riiina Itanrli di-pnsit 
 
 di-|i<)«lt 
 
 
 . rariochi' SI. Panoflip tt'l 
 
 3-J. Coppfr t'anyim deposit 
 
 66. Ilagadore Canyon deposit 
 
 
 
 1. Sin Jii.iiiuin V.iUi-.\ mini- 
 , Super (;>|)suni mini- 
 
 33. Kurnai-e Cri-fk ik-|HJbil 
 
 67. Jami-sim deiKisit 
 
 
 ' 
 
 Ktrn County 
 
 6S. Mliiland deposits 
 
 * 
 
 
 . Tunify Culcli deposit 
 
 «!•. I'.ileii .Miiunlalns deposit 
 
 
 
 ■ . Vallf) Vli» mini- 
 
 34. Bui-na Vista UiW di'i>o«i( 
 3.'i. ('ullcinouod Cri-ili deposit 
 
 70. Hi\er~i(le .Mountains deposit 
 
 71 . Turner delHisil 
 
 , 
 
 - 
 
 Imperial County 
 
 3ti. ('ry-.tal Cyp^um to. di'|K)>it 
 
 '■J. Ware (ie|H)>lt 
 
 
 
 l. Blanr deposit 
 
 37. ruddy Canyon depo.sit 
 
 
 
 
 [ California Uypsum group 
 
 38. (lyiisum Co. of Calirornia de- 
 
 San B«nito County 
 
 
 ■ 
 
 R! Campbill rialms 
 
 posit 
 
 73. .\harez and Tully deposit 
 
 
 J 
 
 I rnviiip Mnnnlain-i drlMsit 
 
 .to HuiuU-l a«i>n.il 
 
 74. Cliambrrs deposit 
 
 ■■ 
 
 S COLLATE 
 
 R^6^2 
 
 California. Division 
 of Mines. 
 
 Call Number: 
 
 TN2U 
 
 C3 
 
 A3 
 
 -GBtOQT 
 
 GEOLOGY 
 
 ^ 
 
 3 1175 00644 1623 
 
o 
 o 
 
 llJ 
 
 ° 0|uo6jon D4UOS 
 
 auiJDOI-UOU 
 
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 OD U. O < O 
 
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GEOLOGY 
 
 SECTION THROUGH THE CHINA RANCH DEPOSIT 
 
 - LINE OF SECTION N 30° E 
 
 "•?' ...» '"•" 
 
 
 SECTION THROUGH THE COPPER CANYON DEPOSIT 
 -LINE OF SECTION N 30° E -— — 
 
 
 EXPLANATION 
 
 
 [0^ .no..™ 
 
 s 
 
 ^ i%5a S'P'"" 
 
 ? 
 
 f m;;| s«... 
 
 ? . 
 
 1 si 1 unconsoii 
 
 £ 
 
 |;'ss 1 Sondilofif 
 
 SECTION THROUGH THE FURNACE CREEK DEPOSIT 
 
 LIBRARY 
 
 UNIVERSITY OF CALIFORNIA 
 DAVIS 
 
 GEOLOGIC SECTIONS ACROSS THREE GYPSUM DEPOSITS - INYO COUNTY, CALIFORNIA 
 
LINE OF SECTION N 80°E 
 
 ' '^15?5 
 
 ''"''^^^^^^^^^^'^^^ 
 
 SECTION A-tf THROUGH "WEST END" DEPOSIT 
 
 SECTION B-B' KELLEY OR BIG GYPSUM HILL DEPOSIT 
 
 SECTION C-C THROUGH SALT BASIN 
 NE 
 
 - LINE OF SECTION N 35 E - 
 
 SCALE 
 800 
 
 EXPLflNflTION 
 
 Qt I Tairoce O'Qval 
 lid giovil 
 
 LO.e. Pl.ocane(7)< 
 
 SECTION 0-D' JUMBO DEPOSIT 
 
 
 Sand 
 
 '"•eg ^J Congiom»roU 
 
 I Brecca'ad groniit 
 
 Age uneeriom Kp;g''-*'w B 
 
 T.TBRARY 
 
 GEOLOGIC SECTIONS ACROSS THE AVAWATZ MOUNTAINS SALT AND GYPSUM DEPOSITS univeksity m- California 
 
 CAVIS 
 
DIVISION OF MINES 
 lAF P. JENKINS, CHIEF 
 
 STATE OF CALIFORNIA 
 DEPARTMENT OF NATURAL RESOURCES 
 
 BULLETIN 163 
 PLATE 3 
 
 SECTION A-A' 
 
 i 
 
 m 
 
 % 
 
 % 
 
 ' fi\i 
 
 sis 
 
 "^n "* 
 
 I Qgl I Alluvium 
 
 SECTION B-B' 
 
 SNOWCLOUD AREA SECTION C-C 
 
 *"0t**-^ Terroce grovel Not shown on mop 
 
 Creioceous ? r«'ngr«'» North groniiic body 
 
 XisvtJ Crystalline limestone 
 
 fslslAj Siliceous limestone 
 
 Tremolitic limestone Not sho*n on 
 geologic mop nor on Section A— A' 
 
 Mono tormotior 
 Pre- CretQceou 
 
 qz- I Quortzite 
 Gypsum 
 
 SNOWCLOUD AREA SECTION D-D' 
 
 rgns ' Green sct>islose rocks 
 
 ^;^c/^ Schistose corbonote rock 
 
 p'"ifg,H Light feispothic quoftzite 
 
 ^(jf'g/?^ Dork felspothic quortzite 
 
 qn 'J Gneiss 
 
 includtd >o 
 uni,lt»ttrttiot»a 
 
 on gaolfiqic map 
 
 LIBRARY 
 
 TTNIVERSITY OF CAUFOPvNli. 
 DAVIS 
 
 STRUCTURE SECTIONS THROUGH THE LITTLE MARIA MOUNTAINS GYPSUM DEPOSITS 
 
DIVISION OF MINES 
 OLAF P. JENKINS, CHIEF 
 
 + 
 
 .". 7Xi>-;-. 
 
 STATE OF CALIFORNIA 
 DEPARTMENT OF NATURAL RESOURCES 
 
 BULLETIN 163 
 PLATE 35 
 
 DENNING SPRINGS was 
 
 CAVE SPRING WASH 
 
 Upper Pliocene 
 
 Lower Pliocene ' 
 (?) 
 
 
 
 Age uncertain < 
 
 LEGEND 
 
 Oo ' Terrace gravels ond alluvium 
 
 Unconformity 
 
 Funeral fanglomerate 
 
 Unconformity 
 
 Post salt beds 
 
 Salt-bearing beds 
 Gypsum-beonng beds 
 
 ^To= Older Tertiary beds 
 Unconformity 
 
 Gronite and metomorphic rocks 
 
 Dionte ond gobbro (intrusive) 
 
 ^■^T-^ Talc 
 
 LIBRARY 
 
 UNIVERSITY OF CALIF . 
 DAVIS 
 
 GEOLOGIC MAP OF THE AVAWATZ MOUNTAINS 
 
 GYPSUM AND SALT DEPOSITS 
 
 SAN BERNARDINO COUNTY, CALIFORNIA 
 
 Modified from o mop by H.R.Johnson and J. 0, Lewis - 191 1 
 
 Publistied by permission of H H Kerktioff Jr 
 
 SatT SPRING 
 
 + 
 
 -Tps , -0° 
 
 ' •-, ^ MULE ■ ^•^A^*^. . \t - • • Xrt 7 
 
TOPOGRAPHT FROM BARREL SPRING 
 
 flNO 
 CARRIZO MOUNTAIN QUADRANGLES 
 
 GEOLOGIC MAP OF THE 
 FISH CREEK MOUNTAINS 
 
 N THE VICINITY OF THE 
 
 US GYPSUM COMPANY QUARRY 
 
 IMPERIAL AND SAN DIEGO COUNTIES, 
 
 CALIFORNIA 
 
 GEOLOGY BY WE VER PLANCK, APRIL 1950 
 AND BY T W DIBBLEE JR 1944 
 
 EXPLANATION 
 
 Recenf [QoI-] Alluvium 
 
 { Tim I Imperial formoli 
 [__ 9 J Gypsum 
 |*c* I Celeslite 
 '^IqCJi Gray member 
 yy\ ^*'' member 
 * I bjC Granilic and metomorphic rocks 
 
 lira '^°"'" 
 
 ' Foulf 
 
 LIBRARY 
 
 UNIVERSITY OF CAUFORMIA 
 DAVIS 
 
 LEGEND 
 
 Spl<t Mounlorn lormt 
 

 SAN FRANCISCOl 
 
 , , A COSTi\,S 
 
 ^9AKLAND'l ^_^-^,?a™ 
 
 \^ 
 
 J MODESTO 
 S,L A U 
 
 GYPSUM DEPOSITS 
 
 Afamcda County 
 
 1. rnidarlnc mine (coal) 
 
 2. Wetliaco Chemical Dlii-lon. 
 Foud Maclilncry & Clicmlcsl 
 loip. 
 
 Buttt County 
 
 3. SI. Claltmliic (hydraulic)* 
 
 Colusa County 
 i. Hiiliy King mine (cniiiict) • 
 J. :iul|iliur Ctcek * 
 
 Frcino County 
 >i, Ruhr deii"''!' 
 7. CiinllnBamlne 
 s. LlltUdcpuslt 
 •.I I.IUlf Panoclic riacer 
 
 10. MiinoclliH- Riilge depo^iit 
 
 1 1. Monocline Kldev depcmlt 
 1:!. TaoU mine 
 
 ly. I'anoclit #1, Panoclie #2 
 U. S.in J...iiiuin V;illi'j mine 
 ]^. Sillier (;)p^um mine 
 Hi. Tumc)- Ciitcti deposit 
 Ii. Valley VIeti mine 
 
 Imptrial Counly 
 
 18. Blanr deposit 
 
 19. ('allfornlo Uypsum group 
 ■JO. Campbell claims 
 
 l!l. Coyoie Mountains deposit 
 
 22. Cnyoie Mountains Sulfur and 
 (iyinum deposit 
 
 23. Klsh Cn-ek Mountains mine 
 M. Sunslilne Placer 
 
 25. Tract 07 
 2«. Trad 71 
 ••7. Tract 72 
 
 ■1%. I'nlfed States Rypsum Com- 
 pany's Plaster City plant 
 
 20. Waters deno%It 
 
 □ independence 
 
 \ 
 
 AVAWATZ 
 
 EXPLANATION 
 o No known production 
 
 • 0— 10,000 Ions 
 
 ® 10,000 — 100,000 tons 
 
 ® Over 100,000 tons 
 
 Inyo County 
 
 30 Blark Muunlnltt. deposit 
 
 31 China llnneli deposit 
 
 32 Copper Canyon deposit 
 
 33. Funiaee Creek deposit 
 
 Kern Counly 
 
 34. Buena VMa l^ke llepo^ll 
 :ir) Cnltnnttood Creek deposit 
 3(i. TryMal [iyi^uffl Co. depusil 
 
 37. Cuddy Canyon deposit 
 
 38. Gypsum Co. of California de- 
 posit 
 
 31). Handel dcpo.lt 
 ta. Jim's n)|i!,um mine 
 41. Koelm Lake deposit 
 42 Ust Hills deposit 
 
 43. Lost Hills mine 
 
 44. MeClure Valley deposits 
 4r>. McKlltrIek deposit 
 
 40. Pacific Cypsum Co deposit 
 47. Paekuood Canyon deposit 
 4R. Ttleplmne IIIIU deposits 
 40. Sunset depoilt 
 
 Kings County 
 
 50. Aienal Gap mine 
 
 51. Dudley deposit 
 
 52. Tulare Lake View group 
 
 Lof Angtlti Counly 
 ■13. Charlie Canyon deposit 
 Q4. Long Beach plant. Kaiser 
 GypMim lileislun. KhImt In- 
 dustries, Inf. 
 5S. Mint Canyon deposit 
 511. Palmdale deposits 
 ST. Southsate plant, Pabco Prod- 
 ucts, Inc. 
 
 Merced County 
 S8. Lot Banos Creek deposit 
 SO. Orllgallta Creek deposit 
 Orange County 
 
 60. Gypsum Canyon deposit 
 
 61. Sycamore Canyon deposit 
 
 Riveriide County 
 t!2 Barili deposit 
 Ii3, Engle Canyon deposit 
 
 \ 
 
 87-0 ■*, 
 CLARK MTS\ 
 
 i. liagjidnre Canyon deposit 
 
 ^'. Midland deposits 
 
 I r.ilen Mountains deposit 
 
 J. Itltersldi- Mountains deposit 
 
 , Turner detioslt 
 
 r Wjiedepoill 
 
 San Btnllo County 
 
 1. Tully deposit 
 
 San Bernardino County 
 I. .\i.inati Mountains deposits 
 I. Bold deposit 
 . Uil'tol Uke di-poslls 
 !. Calico Mouninin-. deposit 
 I. Camp Cady de|K'^lt 
 I. Couchman deposit 
 i. Danliy t^ke deposit 
 '• llnl Hole Spring deposit 
 ', Sliite deiioslt 
 
 San Diego County 
 t. Carriio Creek deposit 
 ). KIpp deposit 
 
 1, National Gypsum Co, deposit 
 . Kotierti and Peeler deposit 
 
 San Joaquin County 
 I- Vernall^ deposit 
 
 San Luii Obispo County 
 . .Mamii Creek depoitis 
 I. Arroyo Grande Creek deposit 
 I. Cnrrlsa mine 
 
 rrlw Plain deposits 
 '. Sliandon deposit 
 
 San Mateo Counly 
 I ReduoDd City plant. Kals'r 
 
 lllviM 
 
 dustrles. Ine. 
 Santa Barbara County 
 
 I. Point Sal mine 
 
 I. Santa Batliara Canyon dei 
 
 . Seeley deposit 
 
 !. Wagon Koad Canyon deposit 
 
 Ventura County 
 I. Ralllniter Canyon deposit 
 
 Canyon deposit 
 
 1 Rlier eluim 
 
 e deposit 
 
 .1 deposit 
 
 p>um mine 
 >. Quaial Canyon depoUt 
 1, HuK'si-ll Borav mine 
 .. Soulli Mountain deposit 
 
 MAP OF THE 
 
 SOUTHERN PORTION OF CALIFORNIA 
 
 SHOWING LOCATIONS OF 
 
 GYPSUM DEPOSITS AND PLANTS 
 
 LIBRARY 
 
 UNIVERSITY OF CALIFORNIA 
 DAVIS 
 
DIVISION OF MINES 
 OLAF P. JENKINS, CHIEF 
 
 STATE OF CALIFORNIA 
 DEPARTMENT OF NATURAL RESOURCES 
 
 BULLETIN 
 PLATE 
 
 GEOLOGIC MAP 
 
 SHOWING GYPSUM 
 RIVERSIDE 
 
 DEPOSITS 
 COUNTY, 
 
 IN THE LITTLE 
 CALIFORNIA 
 
 MARIA MOUNTAINS 
 
 ENLARGED FROM MIDLAND QUADRANGLE 
 
 SCALE 
 
 1000 
 
 2000 FEET 
 
 GEOLOGY BY WE VER PLANCK 
 MARCH, 1949 
 
 • 
 
 LJI'.RAkV 
 
 UNIVERSITY OF CALIFORMIA 
 DAVIS