econstor
Make Your Publications Visible.

A Service of

zbw
Leibniz-Informationszentrum
Wirtschaft
Leibniz Information Centre
for Economics

Ash, Michael; Boyce, James K.

Working Paper

Measuring corporate environmental justice
performance

Working Paper, No. 2008-16

Provided in Cooperation with:
Department of Economics, University of Massachusetts

Suggested Citation: Ash, Michael; Boyce, James K. (2008) : Measuring corporate environmental
justice performance, Working Paper, No. 2008-16, University of Massachusetts, Department of
Economics, Amherst, MA

This Version is available at:
http://hdl.handle.net/10419/64231

Standard-Nutzungsbedingungen:

Die Dokumente auf EconStor dürfen zu eigenen wissenschaftlichen
Zwecken und zum Privatgebrauch gespeichert und kopiert werden.

Sie dürfen die Dokumente nicht für öffentliche oder kommerzielle
Zwecke vervielfältigen, öffentlich ausstellen, öffentlich zugänglich
machen, vertreiben oder anderweitig nutzen.

Sofern die Verfasser die Dokumente unter Open-Content-Lizenzen
(insbesondere CC-Lizenzen) zur Verfügung gestellt haben sollten,
gelten abweichend von diesen Nutzungsbedingungen die in der dort
genannten Lizenz gewährten Nutzungsrechte.

Terms of use:

Documents in EconStor may be saved and copied for your
personal and scholarly purposes.

You are not to copy documents for public or commercial
purposes, to exhibit the documents publicly, to make them
publicly available on the internet, or to distribute or otherwise
use the documents in public.

If the documents have been made available under an Open
Content Licence (especially Creative Commons Licences), you
may exercise further usage rights as specified in the indicated
licence.

www.econstor.eu



DEPARTMENT OF ECONOMICS 
 
 
 
 
 

Working Paper 
 

 
 
 

 
 
 
 

UNIVERSITY OF MASSACHUSETTS 
AMHERST 

 
 

Measuring Corporate Environmental Justice 
Performance 

 
by 
 

Michael Ash and James K. Boyce 
 
 

Working Paper 2008-16 
 



Measuring Corporate Environmental Justice Performance∗

Michael Ash† James K. Boyce‡

October 31, 2008

Abstract

Measures of corporate environmental justice performance can be a valuable tool in
efforts to promote corporate social responsibility and to document systematic patterns
of environmental injustice. This paper develops such a measure based on the extent
to which toxic air emissions from industrial facilities disproportionately impact racial
and ethnic minorities and low-income people. Applying the measure to 100 major
corporate air polluters in the United States, we find wide variation in the extent of
disproportional exposures. In a number of cases, minorities bear more than half of the
total human health impacts from the firm’s industrial air pollution.

Keywords: Corporate social responsibility; corporate environmental performance;
environmental justice; air pollution

JEL codes: M14, Q52, Q56

1 Introduction

This paper analyzes corporate environmental justice performance, measured in terms of the
human health impacts of airborne emissions of toxic chemicals from their industrial facili-
ties. Prior studies of corporate environmental performance (CEP) have focused primarily on
total emissions of pollutants, remediation efforts, or aggregate environmental damage. Prior
studies of environmental justice (EJ) have examined the extent to which hazards dispropor-
tionately impact specific groups, such as racial minorities. To the best of our knowledge,
this paper is the first effort to combine these two strands of research by building a measure
of corporate environmental justice performance (CEJP).

∗Corresponding author: Michael Ash, Department of Economics, Thompson Hall, University of Mas-
sachusetts, Amherst, MA 01003; mash@econs.umass.edu. Acknowledgments: We thank the Ford Foun-
dation and the V.K. Rasmussen Foundation for support of the research. Bengi Akbulut, Grace Chang, Rich
Puchalsky, Helen Scharber, Gül Ünal, and Ann Werboff provided outstanding research assistance and data
management. The authors alone bear responsibility for the analysis.
†Associate Professor, Department of Economics, Center for Public Policy and Administration, and Polit-

ical Economy Research Institute, University of Massachusetts, Amherst
‡Professor, Department of Economics and Political Economy Research Institute, University of Mas-

sachusetts, Amherst

1



The difference between CEP and EJ studies is partly methodological: in CEP, the unit
of analysis is the source of pollution, the firm or an individual facility; in EJ, the unit
of analysis is the receptor, the community or households on the receiving end. They also
differ in their audiences and aims. The main audience for CEP research is socially responsible
managers, investors, and consumers, with the main aim being to improve firm behavior. The
main audience for EJ research is the impacted communities and the responsible government
officials, the main aim being to protect communities from disproportionate hazards.

This paper presents a measure of corporate environmental justice performance, in an
effort to bridge the gap between CEP and EJ research. Our measure is based on data that
link pollution exposures to pollution sources. The audiences for this work span the CEP and
EJ audiences, including both corporate social responsibility advocates who want information
about this important dimension of environmental performance, and environmental justice
advocates who want documentation on systematic patterns in corporate behavior. The paper
is organized as follows.

In Section 2, we describe the datasets and methodology for matching the exposure and
Census data. Our environmental data come from a source-and-receptor model of air-toxics
release and exposure from the U.S. Environment Protection Agency (EPA). We merge the
EPA data with socioeconomic data from the U.S. Bureau of the Census to analyze expo-
sure disparities by race, ethnicity, and income. This facility-level information is aggregated
to obtain firm-level measures using a dataset on corporate ownership of industrial facilities
developed at the Political Economy Research Institute (PERI) of the University of Mas-
sachusetts, Amherst.

In Section 3, we present the CEJP measure, and report the results of applying it to
100 corporations operating throughout the United States. The corporations are those listed
in the latest edition of PERI’s “Toxic 100,” which uses the same data sources to rank the
largest firms in the country on the basis of total human health hazards resulting from air
toxics emissions at their facilities.

In Section 4, we present “worst-in-class” and “best-in-class” rankings for firms in two
industrial sectors that rank high in their air toxics emissions: oil refining; and plastics
and synthetic materials. Community-based EJ activists generally have focused on impacts
from specific facilities, such as the Solutia (former Monsanto) plant in Anniston, Alabama.1

Whether the exposure patterns at individual facilities can be generalized to overall corporate
behavior is seldom evident. Academic EJ researchers generally have focused on the aggregate
pollution loads imposed on people of color and low-income communities, rather than iden-
tifying specific sources of these burdens.2 Whatever the overall extent of disproportionate
impacts, there is no reason to assume that disparities are constant across firms. We show
that the extent to which firms even in the same industrial sector impose disparate pollution
burdens on different groups can and does vary substantially.

In Section 5, we examine the relationship between CEJP and the measure of total hu-
man health risk for the Toxic 100, with the dual aims of assessing whether a measure of

1On the Anniston case, see U.S. Senate Committee on Appropriations [2002] and Bryan [2003].
2See, for example, Ash and Fetter [2004], Pastor et al. [2006], and Mohai and Saha [2007].

2



environmental justice performance adds value to a more conventional measure of CEP, and
of testing the hypothesis that performance in these two dimensions, while not identical, is
positively correlated.

In Section 6, we conclude by discussing potential uses of these data in research on the
determinants and effects of CEJP and in efforts to improve corporate performance.

2 Data and Methods

The underlying data for the CEJP measure come from three sources: the EPA’s Risk-
Screening Environmental Indicators (RSEI); the 2000 U.S. Census of Population and Hous-
ing; and the PERI corporation-facility identification dataset. This section describes these
data sources and how we merge them in order to construct our measure of corporate envi-
ronmental justice performance.

2.1 The RSEI project

First, we describe two sets of data emerging from the EPA’s RSEI project: the aggregated
version which is contained in the EPA’s RSEI public-release data; and the disaggregated
RSEI Geographic Microdata (RSEI-GM) which currently are not available to the public at
large. Our measure relies on the latter, but it is useful first to describe the public-release
data.

2.1.1 The RSEI Project and Public-Release Data

Estimates of exposure to airborne toxics emitted by industrial facilities across the United
States are generated by the RSEI project of EPA. The RSEI project starts with information
on annual releases of more than 600 chemicals from more than 20,000 facilities, reported
in the Toxics Release Inventory (TRI). It then incorporates data on the relative toxicity of
these chemicals, their fate and transport (taking into account chemical breakdown rates,
stack heights, exit-gas velocities, prevailing wind currents, etc.) and the resulting exposures.
For each air release (that is, each facility-chemical pair), RSEI estimates exposures in each
square kilometer of a 101 km × 101 km grid centered on the facility. The EPA publicly
releases facility-level measures of the resulting human health hazards, aggregated over the
10,201 one km-sq cells within the grid and across chemicals. These “RSEI scores” are used
by federal and state environmental officials to prioritize enforcement actions.

The TRI was created at the direction of the Congress under the Emergency Planning and
Community Right-to-Know Act passed in 1986 after the Bhopal chemical plant disaster. The
Act requires industrial facilities to submit annual data to EPA on deliberate and accidental
releases of roughly 600 toxic chemicals into air, surface water, and the ground. TRI data
are available on an annual basis starting in 1987. In 2005, more than 20,000 TRI-reporting
facilities released a total of 1.5 billion pounds of toxic chemicals into the air, and additional
toxics were released from offsite incinerators. The TRI is widely used in both CEP and EJ
literature: CEP studies typically use TRI data on the total mass (pounds) of emissions,
while EJ studies typically analyze the geographical distribution of TRI-reporting facilities
in relation to the demographics of the communities in which they are located.

The TRI data are the jewel in the crown of the environmental “right-to-know” movement

3



in the United States. But valuable as they are, the TRI data have important limitations.
Some of these stem from the nature of the data: the releases are annual totals, estimated,
self-reported, and limited to listed chemicals from qualifying facilities and processes. One of
the most significant limitations is that the TRI simply reports pounds of chemical releases,
often generating press stories that identify local “top polluters” on this basis. Such reporting
does not account for variations in the toxicity of different chemicals, some of which, pound-
for pound, are as much as ten million times more toxic than others. Nor does it take into
account the fate and transport of these chemicals in the environment, or the number of
people impacted. Finally, because the TRI reports facility-by-facility data, the cumulative
impact on communities that are affected by multiple facilities is not evident.3

The RSEI project was launched by the EPA in the mid-1990s to address several of these
limitations. The EPA Office of Pollution Prevention and Toxics (OPPT) processes the TRI
data on the quantity of each chemical released by each facility to create the RSEI. To assess
the human health risks posed by each release, the EPA combines this with information on:
(1) toxicity, or how dangerous the chemical is in terms of chronic human health effects; (2)
fate and transport, or how the chemical spreads from the point of release to the surrounding
area; and (3) population exposure, or how many people live in the affected areas and are
exposed to inhalation of different concentrations of the chemical.

Each air release begins at a stack, leaking valve, open canister, or other source within
the facility, or at the stack of an offsite incineration facility to which it ships wastes. The In-
dustrial Source Complex-Long Term (ISCLT3) model, a Gaussian-plume fate-and-transport
model, is used to map how the chemical spreads from the point of release in the surround-
ing geography.4 EPA combines data on temperature and local wind patterns with facility-
specific information on smokestack height and the exit velocity of released gases, together
with chemical-specific information on molecular weight and rates of deposition and decay,
to estimate the ambient concentrations of each release in each square kilometer within a 101
km by 101 km grid (10,201 sq km) around each facility.

By multiplying the mass (pounds) of each chemical by a toxicity weight, EPA compares
the toxicological significance of releases of different chemicals. The EPA’s toxicity-weighting
system is based on peer-reviewed databases from several sources: the EPA’s Integrated
Risk Information System (IRIS); the EPA’s Office of Pesticide Programs (OPP) Reference
Dose Tracking Reports; the U.S. Department of Health and Human Services Agency for
Toxic Substances and Disease Registry (ATSDR); the California Environmental Protection
Agency (CalEPA) Office of Environmental Health Hazard and Assessment (OEHHA); and
the EPA’s Health Effects Assessment Tables (HEAST). For some chemicals listed in the

3The TRI data capture the largest point-source air pollution emissions in the United States, but they do
not capture emissions from mobile sources, such as trucks, automobiles, ships, and aircraft. The TRI also
excludes facilities that are not required to report by virtue of small size or belonging to non-listed industrial
sectors. Potentially significant air polluters not covered for these reasons include gas stations, dry cleaners,
and auto-body shops.

4Geographic buffers based on plume modeling provide a more accurate picture of exposure to industrial
air releases than do simple circular or distance-weighted buffers [Chakraborty and Armstrong, 1997, Saha
and Mohai, 2005].

4



TRI, no consensus has been reached on the appropriate toxicity weight, and these chemicals
are currently excluded from the RSEI public-release data. In recent years, the excluded
chemicals have represented about one percent of the total mass of reported toxic air releases
nationwide.

Although all TRI chemicals are hazardous, their toxicities vary widely. For carcinogens,
the EPA’s toxicity-weighting system uses inhalation-based dose-response estimates of the
excess lifetime cancer risk per unit of concentration. The toxicity-weighted concentration
is proportional to an individual’s excess risk of cancer from that concentration. For non-
carcinogens, the toxicity-weighting system uses the “Reference Concentration,” which is
the highest level of exposure concentration with no adverse health impact, and expresses
toxicity-weighted exposures as multiples of this (for example, “six times the highest safe
concentration”).

Equivalence between the non-carcinogenic and carcinogenic scales has been set by the
EPA Science Advisory Board at a Reference Concentration being equivalent to a carcinogenic
risk of 250 excess cancer cases per million persons. At the extreme ends of the resulting
toxicity scale for the chemicals on the TRI list, one pound of friable asbestos is equivalent,
in terms of inhalation toxicity, to 27 million pounds of chlorodifluoromethane (HCFC-22).

The RSEI project overlays the grid of toxicity-weighted air pollution concentrations upon
a grid of population data drawn from block-level data from the U.S. Census. The calculation
of aggregate human health risk is based on population exposure to given toxicity-weighted
concentrations. In addition to the number of people in each one-square-kilometer grid cell,
the RSEI’s population weights take into account the age and sex composition of the popu-
lation, because exposure varies by the volume of air inhaled per unit of body weight.5

The RSEI score for a given release (facility-chemical) affecting a given grid cell is:

RSEI Scoref cg =
∑

a

∑
s

Populatonasg × IEFas × Toxicityc × Concentrationf cg (2.1)

where Populatonasg is the population of sex s in age category a in cell g; IEFas is the
inhalation factor for persons of sex s in age category a; Toxicityc is the toxicity weight for
chemical c; and Concentrationf cg is the estimated concentration from the plume model at
cell g for chemical c released by facility f.

The release-cell score, measuring the impact of a given release on a given cell, represents
the total human health risk for the population exposed in that location. In the case of
carcinogens, this score is directly proportional to the number of excess statistical cancer
cases. The EPA’s main objective in creating the RSEI was to assist federal and state agencies
in setting priorities for environmental protection. To this end, the release-cell scores are

5The population-exposure values reflect the cubic meters of air inhaled by a person (roughly 20 cubic
meters per 70 kg) per day. Inhalation exposure factors ranging from 0.165 to 0.341 are used to convert
toxicity-weighted air concentrations into human exposures, according to the following formula: 0.341×(count
of males, aged 0 to 17) + 0.209×(males, 18 to 44) + 0.194×(males, 45 to 64) + 0.174×(males, 65 and Up) +
0.310×(females, aged 0 to 17) + 0.186×(females, 18 to 44) + 0.165×(females, 45 to 64) + 0.153×(females,
65 and Up).

5



aggregated (across chemicals and cells) on a facility-by-facility basis:

RSEI Scoref =
∑

c

∑
g

RSEI Scoref cg (2.2)

The facility-wise RSEI scores are made available to government agencies and the public
on the RSEI public-release data CD-ROM, available for free from EPA. The public-release
data include information on the contribution of each chemical to the facility’s RSEI score,
but they do not include disaggregated information on the geographic cells impacted by the
toxic releases.

The RSEI methodology described above has been subjected to extensive internal and
external reviews, including a peer review by external risk-assessment experts, three peer
reviews by the EPA’s Science Advisory Board, peer reviews by the States, and submission
for public comment.6

2.1.2 The RSEI Geographic Microdata (RSEI-GM)

Because EPA developed the RSEI data for the purpose of prioritizing facilities (that is,
sources) for enforcement and clean-up, the public-release data are not designed for examining
differences among communities (that is, receptors) in terms of their exposure to industrial
toxic releases. The CEJP measure requires use of the disaggregated RSEI-GM data, which
provide 1 km2 cell-by-cell estimates of exposure to airborne toxics identified by source facility
and chemical. The disaggregated data are not available to the public, owing to their daunting
size and complexity. EPA has, however, made the geographic microdata available to the
research community.

At an earlier stage, EPA provided partially disaggregated RSEI data on total estimated
health hazards from air toxics for each of the roughly two million impacted 1 km2 grid cells.
These data were not fully disaggregated; instead they were summed over all releases, i.e.,
aggregated on a cell-by-cell basis across facilities (sources) and chemicals. The aggregate
RSEI score for a cell g is

RSEI Scoreg =
∑

f

∑
c

RSEI Scoref cg (2.3)

where f indexes facility and c indexes chemical. Although these earlier data provided no
distinction among sources, the total human health risk was measured at fine geographic
resolution. By merging this receptor-based measure of aggregate hazards with Census data,
two published EJ studies [Bouwes et al., 2003, Ash and Fetter, 2004] have analyzed hazards
in relation to race, ethnicity, and income using these data for the years 1997 and 1998, re-
spectively. These studies found statistically significant evidence of disproportionate impacts,
both by race and ethnicity (controlling for income) and by income (controlling for race and
ethnicity).

To develop corporation-specific measures of EJ performance, we must use the fully dis-
aggregated geographic microdata, which identify impacts by source facility and receptor cell

6For details, see Office of Pollution Prevention and Toxics [2004].

6



(RSEI scoref g). The RSEI-GM data provide this information. Unlike most other data used
in the investigation of environmental inequalities, the RSEI-GM data offer:

1. National scope and coverage of a wide range of industries, chemicals, and facilities. The
RSEI-GM data include almost all (99 percent by weight) of the air releases reported
to the TRI. The TRI is the most comprehensive list of industrial toxic releases in the
United States, in 2005 covering 494 chemicals and chemical groups released by 23,438
facilities in manufacturing, metal mining, electrical power generation, waste storage
and processing, and chemical storage, as well as Federal facilities. The criteria for
inclusion in TRI reporting include industrial sector and the quantity of toxic chemicals
processed at the facility.

2. Fate, transport, and exposure modeling of all national releases at precise geographic
resolution. The fate-and-transport model permits the unbiased measurement of expo-
sure at receptor sites resulting from point-source air releases, with a high degree of
geographic specificity.7 The focus on exposure at the receptor site outflanks the “How
near is near?” debate in the environmental justice literature as to what distance best
fits the notion of “closeness” to a point source (for discussion, see Boyce [2007]).

3. Identification of the source facility for each pollutant release. The data on ambient con-
centrations of toxics at receptor sites are disaggregated by source facility and chemical.
Unlike the Global Emissions Monitoring System (GEMS) and other pollution-exposure
data based on aggregate levels of pollutants at the receptor site, the RSEI-GM makes it
possible to track each exposure to its source. The simultaneous identification of source
and exposure is perhaps the most important and distinctive strength of the RSEI-GM.

4. Nearly twenty years of annual data spanning the decennial Censuses of 1990 and 2000.
The RSEI-GM time series makes it possible to conduct innovative temporal analysis.
Much of the debate over causality and policy in the environmental justice literature
has revolved around matters of timing: which came first, the people or the pollution?
Longitudinal studies can help us understand the dynamic processes of demographic
and environmental change.

5. Toxicity weighting, expressing the human health risk of emissions per quantity re-
leased. The EPA’s toxicity-weighting system permits comparison of toxic releases from
disparate industrial processes.

6. Construction by well-documented methods that have undergone extensive peer review.
The EPA’s RSEI data are among the most rigorously reviewed environmental datasets
in the nation, and they carry the imprimatur of the Federal regulatory authorities.

In summary, the RSEI-GM database offers a remarkable tool for the analysis of envi-
ronmental justice issues in the United States. Its fine geographic resolution exceeds that

7The 1 square-km resolution of the data does not exhaust the power of the plume model; rather, the
trade-off between geographic specificity and database size determines the scale.

7



of other national exposure databases, such as the National Air Toxics Assessment (NATA).
By measuring exposure, it circumvents the how-near-is-near problem that has plagued EJ
studies based simply on proximity to point sources. Disaggregation by source and chemical
permits the identification of problematic and improving industrial sectors and processes. The
linkage of release and exposure—that is, source and receptor—provided by the RSEI-GM is
unparalleled by any other national dataset. The longitudinal character of the data enables
time-series and panel analyses that can shed light on trends as well as levels of exposure,
and on the dynamic interplay between demographic and environmental change.

The RSEI-GM data thus extend the range and complexity of EJ research questions that
can be feasibly addressed. In this paper, we show how the data can be used to measure
corporate environmental justice performance.

2.2 Census of Population & Housing: The Spatial Join

The 2000 U.S. Census of Population and Housing provides the social, economic, and demo-
graphic data for construction of our measure. Census blocks, defined by roads and other
geographic features, are the smallest geographic unit of data published by the Census. The
data provided at this level include counts of the race, sex, and age of residents. With the
help of local committees, the Census Bureau defines Census block groups, which typically
contain roughly 30 blocks that correspond to neighborhoods, a method that ensures a degree
of socioeconomic homogeneity. Block groups contain 600 to 3,000 people.8 The block group
is the smallest geographic unit for which the Census Bureau publicly releases socioeconomic
data, including counts of the number of people in poverty.

The Census and RSEI-GM data are well-matched in terms of geographic precision, but
they are not in the same geographic format. The RSEI-GM model divides the United States,
including Puerto Rico, into one-square-kilometer cells, of which seven million are within the
101 km × 101 km catchment of at least one industrial facility and almost three million
have positive toxics exposure. Census blocks and block groups have irregular boundaries,
and they can be larger or smaller than one square kilometer. Working with the EPA, its
contractor, and a consortium of academic researchers, we constructed a crosswalk by which
Census geography is spatially joined with the 1 km2 grid-cell data.9 For every cell, the
crosswalk calculates the fraction of the total area of each block that falls into it. In this
way we can count, by age category and sex, the number of poor people, blacks, Latinos,
Asian-Americans, Native Americans, and non-Hispanic whites in each of the 1 km2 cells:

Populationrasg =
∑

b

αgb × Populationrasb (2.4)

where Populationrasg is the estimated population of race or ethnicity r, age a, and sex s in
cell g; Populationrasb is the population of race r, age a, and sex s in Census block b, and αgb
is the share of Census block b that lies in grid cell g. The year 2000 Populationrasb of Census

8Block groups fully partition Census tracts, the next level of aggregation, which on average contain 4,000
residents.

9In addition to the authors, other members of the RSEI-GM research consortium are based at the Uni-
versity of Michigan, the University of Southern California, and the University of California, Berkeley.

8



block b is extracted from the Summary File 1 data from the Census. The crosswalk term,
αgb, is used by the EPA to incorporate population densities in the RSEI project.

Using this method, we obtained age-sex-race/ethnicity population counts for each grid
cell g. Our race/ethnicity population counts, segmented by age-group and sex, were derived
at the 1 km2 grid-cell level from the block-grid spatial merge, using exactly the same method
that the EPA’s RSEI model uses in its total population counts. We then compute:

RSEI Scorerf cg =
∑

a

∑
s

Populatonrasg × IEFas × Toxicityc × Concentrationf cg (2.5)

where Populationrasg is the race or ethnicity r, age a, and sex s population of cell g. Summing
over the 10,201 cells around each facility, the score expresses the aggregate health risk to
minority group r from exposure to a given release:

RSEI Scorerf c =
∑

g

RSEI Scorerf cg (2.6)

For the impact from all of the releases from a single facility,

RSEI Scorerf =
∑

c

∑
g

RSEI Scorerf cg (2.7)

The Census does not report income data at the block level, but only at the block-group
level and higher aggregations (in Census Summary File 3). For this reason, the poverty-
specific population counts are derived from a spatial merge of block-group data with the grid
cells.10 We tested whether applying this broader block-group aggregation to the racial/ethnic
population data caused results to vary much from those obtained from the spatial merge at
the finer block level, and found that there is little difference in the results.

2.3 Corporation-facility matching

To develop corporate performance measures, one more step is required: matching individual
facilities to their corporate parents. PERI’s Corporate Toxics Information Project (CTIP)
has developed a dataset for this purpose. This parent-facility matching requires continu-
ous updating to track mergers and acquisitions, transfers of facilities to new owners, and
the entry of new facilities into the TRI and RSEI databases. Extracting information on
company ownership of facilities from the TRI reports, Dun & Bradstreet’s Million Dollar
Database, Mergent Online, http://www.hoovers.com, company websites, printed reports,
and telephone calls, the CTIP matches facilities to their parent companies.

By aggregating the RSEI scores of the facilities owned by individual parent companies,
the CTIP produces “The Toxic 100,” a ranking of the largest corporations operating in the

10The Census poverty data are reported by age-group but not by sex, and the age-groups are less disag-
gregated than those at the block level used by the RSEI model: where RSEI distinguishes 18 to 44 and 45
to 64, the Census block-group data on the poor report 18 to 64 as a single category. Hence we averaged the
age-specific exposure factors for males and females; for example, (0.341 + 0.310) / 2 = 0.326 for persons
aged 0 to 17. For the combined age group, we computed a span-weighted average: (27/47×(0.209 + 0.186)/2
+ 20/47×(0.194+0.165))/2) = 0.190 for persons aged 18 to 64.

9

http://www.hoovers.com


United States on the basis of the total human health risk from air toxics emissions from
their facilities, as measured by the RSEI data. The most recent edition of the Toxic 100
(available at http://www.peri.umass.edu/toxic100/) identifies the top polluters among
the companies that appeared in the year 2007 on the Fortune 500, Fortune Global 500, and
S&P 500 lists of the country’s largest corporations, and on the Forbes Global 2000 list of the
largest 500 U.S.-based and 500 foreign-based corporations. The most recent available RSEI
data from EPA refer to the year 2005. The Toxic 100 therefore reports 2005 air pollution
from industrial facilities in the United States, based on the latest available (2007) data on
ownership structure.

3 A Measure of Corporate Environmental Justice Performance

In this section we present our measure of corporate environmental justice performance
(CEJP) for the 100 large firms that appear in the latest edition of PERI’s Toxic 100. The
measure indicates the extent to which the human health impacts from releases of toxic air
pollutants at industrial facilities owned by the corporation are borne by specific subgroups
of the U.S. population. Two CEJP indicators are reported here: the first measures impacts
on racial and ethnic minorities, and the second measures impacts on people with incomes
below the national poverty line.

3.1 Measuring group shares of human health risk

To measure human health risk for a given corporation, we aggregate the race/ethnicity-
specific and poverty-specific scores for the facilities it owns:

RSEI ScorerF =
∑
f∈F

RSEI Scorerf (3.1)

where r indexes racial/ethnic or poverty categories, and f indexes facilities owned by firm
F .

Our CEJP measure is the percentage share of these groups in the total human health
risks generated by air toxics releases from the firm’s facilities. To obtain this, we divide this
score by the total RSEI score for the firm, as reported in the Toxic 100:

CEJPrF ≡ RSEI ScorerF /RSEI ScoreF (3.2)

CEJP is a purely distributional measure, in that it does not distinguish between a dis-
proportionate share of a small total human health impact and a disproportionate share of
a large total impact. We examine the relationship between the CEJP measure and total
pollution impacts in Section 5.

To assess whether the share of impacts accruing to specific population groups is “dis-
proportionate,” we must choose an appropriate counterfactual to define a “proportionate”
impact. The most straightforward benchmark for this purpose is the share of the group in
the national population. In the 2000 Census, racial and ethnic minorities11 constituted 31.8

11We classify as minority all persons reporting either Hispanic for ethnicity or a response other than white

10

http://www.peri.umass.edu/toxic100/


percent of the U.S. population, and people living below the official poverty line were 12.9
percent.

Alternative benchmarks for assessing disproportionality include the share of the group
in the population of the specific regions—for example, states or metropolitan areas—in
which the firm’s facilities are located, or their share in the firm’s labor force. A region-
specific benchmark would be consistent with the view that the facility siting decisions of
firms are often “within-region” choices, constrained by the desire to locate within a certain
part of the country for ease of access to input or output markets [Pastor et al., 2001].
An employment-based benchmark would provide a rough gauge of the balance between
“costs” and “benefits” to specific groups, sometimes invoked in discussions of the supposed
“jobs-versus-environment” tradeoff. Both alternatives would apply different benchmarks to
different firms, complicating the task of inter-firm comparisons.

Our CEJP measure can be compared to these and other benchmarks. In the tables
presented here, we report national population shares as the simplest, and for our purposes
most robust, standard for comparison.

It is also of interest to see how a specific firm compares with other firms. For this
purpose, our tables also show group shares of human health hazards aggregated over all
firms and facilities in the RSEI-GM database and aggregated over the universe of the large
firms represented in the Toxic 100. For all firms, the share of minorities and the poor in 2005
were 34.8 percent and 15.3 percent, respectively (above their respective national population
shares of 31.8 percent and 12.9 percent). The shares for the Toxic 100 firms were slightly
lower than for all firms, but still above the shares of these groups in the national population.

Inter-firm comparisons can also be made within specific industrial sectors. To illustrate,
we report “best-in-class” and “worst-in-class” CEJP measures for firms in the plastics and
oil refining sectors below.

3.2 Results

Table 1 reports the CEJP minority measure for the top ten firms ranked on this basis from
the firms in the Toxic 100. In all ten cases, more than half of the human health impacts
resulting from the firm’s air toxics releases are borne by minority groups. Two of these
firms— Exxon Mobil and Arcelor Mittal—also rank in the top ten of The Toxic 100 itself; in
other words, they rank very high in total pollution burden as well as the share of the burden
borne by minorities. In both cases, the main subgroup contributing to the large impact
on minorities is blacks. In the case of Exxon Mobil, the black share of total human health
impacts is 55.5 percent—the highest share of any firm in the Toxic 100.

[INSERT TABLE 1 HERE]
Looking at the bottom three lines in Table 1, we can compare group shares of health

hazards for all firms in the Toxic 100 and the entire RSEI-GM database to their shares in

for race. The breakout columns for blacks, Asians and Pacific Islanders, Native Americans refer to persons
reporting exactly one race and non-Hispanic ethnicity. The breakout column for Hispanics may refer to
people of any race. Because of the multiracial and other categories, the breakout columns do not sum to the
total for minorities.

11



the U.S. population. Again, the disproportionate burden borne by blacks is evident: their
share of the total pollution burden (18.1 percent) is more than 50 percent greater than
their share of the national population (11.8 percent). In the case of Hispanics, Asian-Pacific
islanders, and American Indians, their shares of the total pollution burden are somewhat
below their shares of the national population. This is consistent with the finding of Ash and
Fetter (2004) that within metropolitan statistical areas (MSAs), Hispanics tend to live in
significantly more polluted neighborhoods than non-Hispanic whites, but that this effect is
moderated in national-level data by the fact that they tend to live in MSAs that have less
industrial toxic air pollution than the national average. In the case of blacks, by contrast,
Ash and Fetter (2004) found that they not only live “on the wrong side of the environmental
tracks” at the MSA level, but also are concentrated in MSAs with above-average industrial
air toxics pollution.

Table 2 reports the CEJP poverty measure, again for the top ten firms ranked on this
basis from the Toxic 100. Not surprisingly, there is considerable overlap with Table 1: seven
firms place in both lists. In the cases of the top two firms—National Oilwell Varco and
Hess—the share of human health impacts borne by people living below the poverty line
is more than double their share in the national population. Three firms that rank in the
top ten by the CEJP poverty measure—Exxon Mobil, Arcelor Mittal, and Archer Daniels
Midland—also rank in the top ten of the Toxic 100 itself.

[INSERT TABLE 2 HERE]
The Appendix Table presents these measures for all of the firms in the Toxic 100 universe,

together with their Toxic 100 rank, number of TRI-reporting facilities, number of releases
(that is, chemical-facility combinations), and total human health hazard (RSEI) score. The
firms with the highest shares for Hispanics, Asian/Pacific Islanders, and Native Americans
are, respectively, Freeport-McMoran Copper & Gold, Avery Dennison, and Northeast Utili-
ties; in each case, the share of these subgroups in the firm’s human health impacts is more
than three times their share in the national population.

3.3 Environmental justice performance at the facility level

Two factors enter into a firm’s CEJP score. The first is the share of minority or poverty
groups in the human health impacts of all its facilities, averaged over the number of facilities.
The second is the extent to which its “dirtiest” facilities—that is, the facilities with the
highest total RSEI scores—are located in places where these shares are higher (or lower)
than average.

To illustrate this point, we examine facility-level measures of environmental justice per-
formance for Exxon Mobil, the corporation with the highest share of total impacts borne by
blacks. Table 3 presents data for the firm’s top five facilities, ranked by RSEI scores, and
for a composite of the fifty other Exxon Mobil facilities that contribute to the firm’s score.
It is evident that the top two facilities, both of which are in Baton Rouge, Louisiana, drive
the result for blacks. It is also noteworthy that the next two facilities, refineries in Baytown,
Texas, and Torrance, California, both have exceptionally large shares of Hispanics and, in
the case of Torrance, Asian/Pacific-islanders.

12



[INSERT TABLE 3 HERE]

4 Best and worst “in class” rankings

This section investigates whether inter-firm differences in environmental justice performance
persist within specific industrial sectors, taking as examples two particularly “dirty” sectors,
the manufacture of plastics (and other synthetic materials) and oil refining. Because firms
often are diversified—owning facilities in a number of different industrial sectors—we restrict
the comparison to facilities in the sectors of interest. The TRI and RSEI data include SIC
(Standard Industrial Classification) codes for each reporting facility; we use these to select
the relevant set of facilities for each firm.12

Tables 4 and 5 report the CEJP scores for firms in the oil and plastics/synthetics sectors,
respectively. To conserve space, we report scores only for firms whose total human health
hazard from air emissions from facilities in the relevant sector surpass a threshold level.13

The firms are ranked from “best-in-class” to “worst-in-class” on the basis of the share of
human health impacts borne by minority groups.14 In the case of the oil industry, Tesoro,
Marathon Oil, and Sunoco achieve best-in-class rankings, with minorities accounting for less
than 35 percent of the impacts, although Tesoro is the only ranked firm whose minority share
of health impacts is below the minority share in the U.S. population at large (31.8 percent).
The worst-in-class rankings go to Pasadena Refining, ExxonMobil, and Hess: minorities
account for more than 67 percent of the impacts from their oil-refining facilities.

[INSERT TABLE 4 HERE]
In the case of the plastics and synthetic materials sector, Neville Chemical Co., Eastman

Chemical, and High Voltage Engineering Corporation achieve best-in-class rankings, with
minorities accounting for less than 12 percent of the impacts. The worst-in-class rankings in
this sector go to BP, ExxonMobil, and Resinall Corporation, with minorities accounting for
more than 60 percent of the impacts.

[INSERT TABLE 5 HERE]

5 Total Human Health Impact and CEJP

The relationship between corporate environmental performance (CEP), here measured in
terms of total human health impact from air toxics emissions at facilities owned by the firm,
and corporate environmental justice performance (CEJP) is of interest for three reasons.

First, if the correlation between these two dimensions of performance were extremely
high—that is, the biggest polluters also had the biggest shares of minorities and the poor in

12Oil-refining facilities correspond to three-digit SIC code 291; plastics and synthetic materials manufac-
turing facilities correspond to four-digit SIC codes 2820–2824. Some facilities engage in production activities
in multiple industrial sectors, for which they can report up to six SIC codes. We select all facilities that
report production in the relevant codes.

13As a cutoff, we use a combined RSEI score of 5,000 for the relevant facilities.
14Rankings based on the share borne by people with incomes below the poverty line (reported in the last

column of the tables) yield similar results.

13



the resulting health impacts—then the calculation of a separate CEJP measure might not
be worth the effort: CEP would tell us all we need to know.

Second, there are plausible a priori reasons to expect that the correlation between the
two will be positive, albeit imperfect. The reason is that where inequalities of power and
wealth between polluters and the “pollutees” who bear environmental costs are larger, one
outcome is likely to be a larger overall magnitude of pollution. Wealth inequalities can yield
this result under the standard assumptions of benefit-cost analysis, in which the value of an
adverse health impact is measured in terms of a person’s willingness to pay to avoid it. To
put matters bluntly, in this calculus the health and lives of the poor are worth less than
those of the rich.

Where the society’s decisions about environmental policies are shaped by political influ-
ence, in addition to benefit-cost calculations, power inequalities can further contribute to this
outcome. For example, Boyce [2002] has suggested that environmental policies are governed
by a “power-weighted social decision rule,” in which what matters is not only the monetary
values of costs and benefits but also the power of the parties to whom these accrue. The
relationship between CEP and CEJP can provide one test of this hypothesis.

A final reason why this relationship is worth examining is that if, instead of a positive
correlation, the two were inversely related—such that disproportional impacts were concen-
trated among relatively minor polluters—then this might mitigate, to some degree, findings
of environmental injustice.

To examine this relationship, we looked at plotted total RSEI scores against our CEJP
measures for the firms appearing in The Toxic 100. The results are shown in Figures 1 and
2 for the CEJP minority and poverty measures, respectively. In both cases, the results show
a weak positive relationship, consistent with the expectation that the overall magnitude of
pollution will be correlated with the distribution of the resulting burdens, but not so strongly
correlated as to obviate the need for measures of the latter.

[INSERT FIGURES 1 & 2 HERE]
Fitting linear regression lines to the 100 observations in each figure, we find that as the

minority share rises from 0 to 80 percent, the extent of observed variation, the predicted
human health hazard rises by 27 percent. As the poverty share rises from 0 to 30 percent,
the small range of variation in poverty shares, the predicted human health hazard rises by
150 percent.

6 Conclusions

The measure of corporate environmental justice performance (CEJP) presented in this paper
provides meaningful new information on an important dimension of corporate behavior. For
ethical reasons, it is of interest to know not only how much pollution is released by a firm’s
industrial facilities, but also how the resulting human health impacts are distributed across
racial, ethnic, and income groups. The CEJP measure provides this information.

Apart from ethical concerns, there may be good legal and financial reasons for corpora-
tions and investors to pay attention to this dimension of firm performance. Environmental

14



justice—defined in terms of both race/ethnicity and income class—became an explicit objec-
tive in federal government policy making in 1994, when President Clinton signed Executive
Order 12898 directing each government agency to take steps to identify and rectify “dis-
proportionately high and adverse human health or environmental effects of its programs,
policies, and activities on minority populations and low-income populations.” In the case
of minorities, moreover, systematically disproportionate burdens could prove to be grounds
for legal challenges under the U.S. Civil Rights Act. Public and private responses could
translate environmental injustice into liabilities that affect the firm’s bottom line.

Regular measurement of CEJP can provide stakeholders—investors, managers, regula-
tors, consumers, and residents of affected communities—with a report card for assessing
levels and changes in performance. Furthermore, because the fate-and-dispersion model can
be used to estimate concentrations from hypothetical releases, it can be used to predict the
environmental and EJ impacts of planned expansions or decreases in air toxics emissions.

The CEJP measure is scalable, and as we demonstrated above, it can be used to compare
both firms and facilities within firms. It can be readily extended to specific industrial sectors,
specific chemicals, or other classifications of industrial point-source pollution.

We believe that the joint measurement of total impact (CEP) and disparate impacts
(CEJP) provides the most robust picture of corporate environmental performance. Al-
though correlated, neither measure adequately conveys information about the other. Both
dimensions are relevant, and both should—and can—be incorporated into the assessment of
corporate behavior.

References

Michael Ash and T. Robert Fetter. Who Lives on the Wrong Side of the Environmental
Tracks? Social Science Quarterly, 85(2):441–462, 2004.

Nicolaas W. Bouwes, Steven Hassur, and Marc Shapiro. Information for Empowerment: The
EPA’s Risk-Screening Environmental Indicators Project. In James K. Boyce and Barry G.
Shelley, editors, Natural Assets: Democratizing Environmental Ownership, pages 135–150.
Washington, DC: Island Press, 2003.

James K. Boyce. The Political Economy of the Environment. Edward Elgar, 2002.

James K. Boyce. Inequality and Environmental Protection. In Jean-Marie Baland, Pranab
Bardhan, and Samuel Bowles, editors, Inequality, Collective Action, and Environmental
Sustainability, pages 314–348. Princeton: Princeton University Press, 2007.

Dave Bryan. Minority Groups Mobilize on Pollution: Alabama Towns Battle for PCB
Cleanup Reflects Fight Against ‘Environmental Racism’. Associated Press, 6 April 2003.
http://www.ejrc.cau.edu/washpostejarticle.html.

J. Chakraborty and M. P. Armstrong. Exploring the use of buffer analysis for the identifica-
tion of impacted areas in environmental equity assessment. Cartography and Geographic
Information Systems, 24(3):145–157, 1997.

15

http://www.ejrc.cau.edu/washpostejarticle.html


Paul Mohai and Robin Saha. Racial Inequality in the Distribution of Hazardous Waste: A
National-Level Reassessment. Social Problems, 54(3):343–370, 2007.

Office of Pollution Prevention and Toxics. Risk-Screening Environmental Indicators. U.S.
Environmental Protection Agency, Washington, DC, 2004. Accessed February 1, 2008.
URL: http://www.epa.gov/oppt/rsei.

Manuel Pastor, James Sadd, and John Hipp. Which Came First? Toxic Facilities, Minority
Move-in, and Environmental Justice. Journal of Urban Affairs, 23(1), 2001.

Manuel Pastor, James Sadd, and Rachel Morello-Frosch. The Air is Always Cleaner on
the Other Side: Race, Space, and Air Toxics Exposures in California. Journal of Urban
Affairs, 27(2), 2006.

Robin Saha and Paul Mohai. Historical Context and Hazardous Waste Facility Siting: Un-
derstanding Temporal Patterns in Michigan. Social Problems, 2005.

U.S. Senate Committee on Appropriations. PCB Contamination in Anniston, Al-
abama. 107th Congress, 19 April 2002. Available at http://www.ewg.org/files/
AnnistonSenateHearingTrans.pdf.

16

http://www.epa.gov/oppt/rsei
http://www.ewg.org/files/AnnistonSenateHearingTrans.pdf
http://www.ewg.org/files/AnnistonSenateHearingTrans.pdf


Figure 1. Total Human Health Impact and CEJP for Minorities: Toxic 100

●

●

●

●

●

●

●
● ●

●
●

● ●
● ● ●

● ●
●● ● ●●●● ●●●

●
●●

● ● ●●● ●●● ● ● ●●●● ● ● ●● ●●● ●●● ●● ●● ●● ●● ●●●● ●●● ●●● ● ●● ● ●● ●● ●● ●●● ● ●● ●● ● ● ● ●●●● ●● ●

0 20 40 60 80

0
5

0
0

0
0

1
0

0
0

0
0

1
5

0
0

0
0

2
0

0
0

0
0

2
5

0
0

0
0

Minority Share

S
co

re

E.I. du Pont de Nemours

Archer Daniels Midland (ADM)

Dow Chemical

Bayer Group

Eastman Kodak

General Electric

Arcelor Mittal
US Steel ExxonMobil

AK Steel Holding
Eastman Chemical

Source: Toxic 100 Corporate RSEI Score and Appendix Table 1.

17



Figure 2. Total Human Health Impact and CEJP for Poverty: Toxic 100

●

●

●

●

●

●

●
● ●

●
●

● ●
●● ●

● ●
●●● ●●● ●●● ●
●
●●

●● ●●● ●● ●●● ●● ●●● ● ●●●● ●●●●●● ●● ●● ●●●●● ●●● ● ● ●●● ●● ● ●● ●● ●● ●●● ●● ●●● ●●● ●●●● ●●●

0 20 40 60 80

0
5

0
0

0
0

1
0

0
0

0
0

1
5

0
0

0
0

2
0

0
0

0
0

2
5

0
0

0
0

Poor Share

S
co

re

E.I. du Pont de Nemours

Archer Daniels Midland (ADM)

Dow Chemical

Bayer Group

Eastman Kodak

General Electric

Arcelor Mittal
US Steel ExxonMobil

AK Steel Holding
Eastman Chemical

Source: Toxic 100 Corporate RSEI Score and Appendix Table 1.

18



Table 1. Corporate Environmental Justice Performance: Minorities

Minority Black Hispanic Asian/Pacific Nat. Am.
Share Share Share Share Share

National Oilwell Varco 78.0 22.3 53.0 2.0 0.7
ExxonMobil 69.1 55.5 10.4 2.2 0.3
General Dynamics 69.0 11.1 49.1 6.7 1.0
Hess 66.5 15.6 47.6 4.9 0.3
Freeport-McMoran Copper &
Gold

62.1 2.9 57.1 0.5 1.6

Arcelor Mittal 61.6 46.6 12.5 1.3 0.3
Valero Energy 59.9 38.7 18.3 1.8 0.5
Akzo Nobel 58.6 44.4 10.4 2.4 0.3
Public Service Enterprise Group
(PSEG)

57.0 18.2 26.8 10.1 0.4

Northrop Grumman 56.6 49.8 3.3 1.8 0.4
Toxic 100 Firms 34.2 19.8 10.5 2.1 0.5
All Firms 34.8 18.1 12.6 2.2 0.6
US Population 31.8 11.8 13.7 3.7 0.7

19



Table 2. Corporate Environmental Justice Performance: People in Poverty

Poor
Share

National Oilwell Varco 26.5
Hess 26.4
ExxonMobil 25.4
Akzo Nobel 25.2
Arcelor Mittal 24.9
Northrop Grumman 22.6
Archer Daniels Midland (ADM) 22.5
Rowan Cos. 21.6
Nucor 21.2
General Dynamics 20.9
Toxic 100 Firms 15.2
All Firms 15.3
US Population 12.9

20



Table 3. Minority and Poverty Shares of Airborne Human Health Risk: ExxonMobil Facilities

Minority Black Hispanic Asian/Pacific Nat. Am. Poor
Score Share Share Share Share Share Share

Baton Rouge Refinery (LA) 62269 78.0 75.3 1.1 1.0 0.1 31.1
Baton Rouge Chemical (LA) 24748 73.1 70.0 1.2 1.1 0.1 29.1
Baytown Refinery (TX) 18405 54.6 15.0 35.8 2.6 0.5 15.3
Torrance Refinery (CA) 6710 69.9 10.8 40.9 15.5 0.7 15.1
Joliet Refinery (IL) 6277 33.7 16.5 13.0 2.9 0.2 7.8
50 Additional Facilities 10347 50.8 23.2 23.4 2.6 0.8 17.3
55 Total Facilities 128758 69.1 55.5 10.4 2.2 0.3 25.4

21



T
ab

le
4.

M
in

or
it

y
an

d
P

ov
er

ty
S

h
ar

es
of

A
ir

b
or

n
e

H
u

m
an

H
ea

lt
h

R
is

k:
O

il
R

efi
n

in
g

M
in

or
it

y
B

la
ck

H
is

p
an

ic
A

si
an

/P
ac

ifi
c

N
at

.
A

m
.

P
oo

r
F

ac
il

it
ie

s
R

el
ea

se
s

S
co

re
S

h
ar

e
S

h
ar

e
S

h
ar

e
S

h
ar

e
S

h
ar

e
S

h
ar

e
E

xx
on

M
ob

il
8

56
4

11
53

70
65

.5
51

.9
10

.2
2.

4
0.

3
24

.6
C

on
oc

oP
h

il
li

p
s

17
79

0
90

47
8

34
.8

19
.6

10
.6

2.
3

0.
9

15
.4

V
al

er
o

E
n

er
gy

17
10

31
83

41
6

59
.8

38
.6

18
.3

1.
8

0.
5

19
.7

B
P

6
38

6
48

84
1

56
.2

16
.4

32
.6

5.
8

0.
6

16
.3

C
it

go
P

et
ro

le
u
m

C
or

p
.

7
31

4
29

36
4

47
.8

28
.5

15
.7

2.
3

0.
4

19
.4

P
as

ad
en

a
R

efi
n
in

g
S

ys
te

m
In

c.
1

36
25

29
1

73
.6

12
.6

57
.7

2.
4

0.
6

25
.1

S
u

n
oc

o
5

17
6

24
89

6
34

.0
22

.9
5.

8
3.

8
0.

3
16

.3
T

es
or

o
6

31
5

24
64

0
24

.5
2.

6
11

.6
5.

9
1.

8
10

.0
S

u
n

co
r

E
n

er
gy

1
35

20
37

8
45

.3
6.

9
33

.6
2.

5
1.

3
12

.9
M

ot
iv

a
E

nt
er

p
ri

se
s

L
.L

.C
.

5
17

3
14

70
7

42
.2

35
.6

4.
1

1.
4

0.
3

16
.8

H
es

s
2

11
0

12
56

4
67

.4
14

.6
49

.8
4.

9
0.

3
26

.9
S

in
cl

ai
r

O
il

C
or

p
.

3
17

1
12

45
9

35
.3

18
.2

6.
8

1.
1

5.
3

20
.3

R
oy

al
D

u
tc

h
S

h
el

l
6

29
1

11
43

0
43

.5
8.

8
25

.5
6.

0
1.

0
12

.2
M

ar
at

h
on

O
il

7
36

4
11

27
7

33
.8

16
.3

13
.6

1.
9

0.
6

14
.3

C
h

ev
ro

n
7

43
2

55
84

66
.2

17
.4

31
.9

13
.3

0.
6

18
.9

A
ll

O
il

R
efi

n
in

g
16

3
68

36
55

52
98

51
.3

27
.9

18
.8

2.
9

0.
7

19
.0

A
ll

F
ir

m
s

10
26

36
16

47
0

14
57

69
82

34
.8

18
.1

12
.6

2.
2

0.
6

15
.3

U
S

P
op

u
la

ti
on

−
−

−
31

.8
11

.8
13

.7
3.

7
0.

7
12

.9

22



T
ab

le
5.

M
in

or
it

y
an

d
P

ov
er

ty
S

h
ar

es
of

A
ir

b
or

n
e

H
u

m
an

H
ea

lt
h

R
is

k:
P

la
st

ic
s

an
d

S
yn

th
et

ic
M

at
er

ia
ls

M
in

or
it

y
B

la
ck

H
is

p
an

ic
A

si
an

/P
ac

ifi
c

N
at

.
A

m
.

P
oo

r
F

ac
il

it
ie

s
R

el
ea

se
s

S
co

re
S

h
ar

e
S

h
ar

e
S

h
ar

e
S

h
ar

e
S

h
ar

e
S

h
ar

e
E

.I
.

d
u

P
on

t
d

e
N

em
ou

rs
25

73
2

22
22

29
37

.1
31

.6
2.

8
1.

0
0.

3
17

.9
E

as
tm

an
C

h
em

ic
al

4
25

2
98

29
2

9.
9

6.
4

1.
7

0.
6

0.
2

15
.1

A
p

ol
lo

M
gt

.
(H

ex
io

n
S

p
ec

ia
lt

y
C

h
em

.)
23

37
0

62
76

6
40

.3
14

.8
22

.1
2.

1
0.

5
13

.2
D

ow
C

h
em

ic
al

23
11

81
62

80
6

43
.4

17
.1

23
.9

1.
3

0.
4

15
.0

N
ev

il
le

C
h

em
ic

al
C

o.
1

22
28

49
8

7.
6

4.
9

0.
6

1.
2

0.
1

6.
6

E
xx

on
M

ob
il

9
28

9
26

77
0

71
.7

66
.3

3.
4

1.
2

0.
2

28
.3

B
A

S
F

13
14

0
22

57
9

31
.3

22
.8

4.
7

1.
4

0.
4

13
.0

In
vi

st
a

S
.

A
.

R
.

L
.

7
10

6
17

58
0

26
.5

20
.1

3.
8

0.
6

0.
5

13
.7

B
P

2
20

3
14

86
4

77
15

.0
44

.3
15

.4
0.

8
20

.6
Z

eo
n

C
h

em
ic

al
s

L
P

2
23

14
75

9
17

11
.5

2.
1

1.
6

0.
2

8.
7

R
es

in
al

l
C

or
p

.
2

21
14

15
0

62
.5

60
.2

1.
2

0.
3

0.
4

32
.3

G
en

er
al

E
le

ct
ri

c
8

22
5

12
54

1
10

5.
6

2.
0

1.
0

0.
2

11
.5

S
te

p
an

C
o.

1
25

12
34

5
35

.1
18

.2
12

.8
2.

8
0.

2
8.

2
G

eo
rg

ia
G

u
lf

C
or

p
.

3
13

5
11

13
8

45
.7

41
.7

1.
8

1.
3

0.
3

22
.5

C
yt

ec
In

d
u

st
ri

es
In

c.
7

10
8

10
95

7
12

.3
6.

0
3.

2
1.

1
0.

5
14

.1
L

an
xe

ss
3

43
10

54
9

17
.4

11
.7

2.
8

1.
5

0.
2

9.
9

L
u

b
ri

zo
l

C
or

p
.

8
14

7
10

21
1

21
.1

14
.7

2.
7

1.
7

0.
3

12
.7

R
oy

al
D

u
tc

h
S

h
el

l
1

63
88

24
48

.2
10

.3
34

.2
2.

7
0.

5
13

.0
U

.
S

.
P

ol
ym

er
s

A
cc

u
re

z
L

L
C

1
10

83
97

24
.8

17
.6

3.
0

1.
6

0.
4

18
.3

R
oh

m
an

d
H

aa
s

14
32

3
79

55
25

.1
17

.1
2.

7
3.

6
0.

3
21

.3
H

er
cu

le
s

In
c.

5
32

73
66

40
.2

21
.5

15
.3

1.
7

0.
5

20
.8

M
it

su
b

is
h

i
C

h
em

ic
al

2
20

69
06

20
.8

12
.5

4.
3

2.
6

0.
2

10
.6

H
ig

h
V

ol
ta

ge
E

n
gi

n
ee

ri
n

g
C

or
p

.
1

4
65

55
11

.2
3.

0
5.

5
1.

9
0.

2
6.

2
W

it
co

C
or

p
.

2
62

65
53

38
.8

34
.5

2.
3

1.
1

0.
2

16
.9

W
es

tl
ak

e
O

le
fi

n
s

C
or

p
.

4
42

63
52

38
.3

34
.1

2.
0

1.
2

0.
2

16
.5

S
ol

u
ti

a
In

c.
5

72
63

36
29

20
.5

5.
6

0.
9

0.
9

15
.2

G
oo

d
ye

ar
2

30
61

85
58

.6
20

.7
33

.7
3.

3
0.

4
18

.5
M

ic
h

el
in

G
ro

u
p

1
17

54
36

35
.5

31
.5

1.
5

0.
7

0.
2

17
.0

In
n

ov
en

e
U

S
A

L
L

C
3

69
54

04
24

.1
19

.1
1.

9
0.

6
0.

2
16

.7
A

ll
P

la
st

ic
s

54
3

88
98

84
74

04
34

.1
22

.6
8.

3
1.

6
0.

3
16

.0
A

ll
F

ir
m

s
10

26
36

16
47

0
14

57
69

82
34

.8
18

.1
12

.6
2.

2
0.

6
15

.3
U

S
P

op
u

la
ti

on
−

−
−

31
.8

11
.8

13
.7

3.
7

0.
7

12
.9

23



A
p

p
e
n

d
ix

T
a
b

le
1
.

M
in

o
ri

ty
a
n

d
P

o
v
e
rt

y
S

h
a
re

s
o
f

A
ir

b
o
rn

e
H

u
m

a
n

H
e
a
lt

h
R

is
k
:

T
o
x
ic

1
0
0

C
o
rp

o
ra

ti
o
n

s

T
o
x
ic

1
0
0

R
S

E
I

M
in

o
ri

ty
B

la
ck

H
is

p
a
n

ic
A

si
a
n

/
P

a
c
ifi

c
N

a
t.

A
m

.
P

o
o
r

R
a
n

k
F

a
c
il
it

ie
s

R
e
le

a
se

s
S

c
o
re

S
h

a
re

S
h

a
re

S
h

a
re

S
h

a
re

S
h

a
re

S
h

a
re

E
.I

.
d

u
P

o
n
t

d
e

N
e
m

o
u

rs
1

5
8

1
2
7
7

2
8
5
6
6
1

3
6
.0

2
9
.9

3
.4

1
.0

0
.4

1
7
.3

A
rc

h
e
r

D
a
n

ie
ls

M
id

la
n

d
(A

D
M

)
2

3
4

2
1
1

2
1
3
1
5
9

3
2
.0

2
5
.9

2
.7

1
.1

0
.2

2
2
.5

D
o
w

C
h

e
m

ic
a
l

3
4
1

1
4
1
5

1
8
9
6
7
3

4
2
.7

1
5
.0

2
3
.6

2
.8

0
.4

1
3
.0

B
a
y
e
r

G
ro

u
p

4
1
6

2
8
9

1
7
2
7
7
3

2
4
.3

3
.2

1
8
.5

1
.4

0
.4

6
.8

E
a
st

m
a
n

K
o
d

a
k

5
6

1
4
2

1
6
2
4
3
0

2
6
.2

1
4
.2

8
.2

2
.0

0
.3

1
3
.4

G
e
n

e
ra

l
E

le
c
tr

ic
6

1
3
0

8
2
8

1
4
9
0
6
1

3
2
.4

1
1
.7

1
6
.1

2
.7

0
.5

1
3
.4

A
rc

e
lo

r
M

it
ta

l
7

2
4

3
0
4

1
3
4
5
7
3

6
1
.6

4
6
.6

1
2
.5

1
.3

0
.3

2
4
.9

U
S

S
te

e
l

8
1
2

2
8
1

1
2
9
1
2
3

3
6
.8

2
9
.3

4
.6

0
.9

0
.4

1
7
.8

E
x
x
o
n

M
o
b

il
9

5
5

1
4
5
2

1
2
8
7
5
8

6
9
.1

5
5
.5

1
0
.4

2
.2

0
.3

2
5
.4

A
K

S
te

e
l

H
o
ld

in
g

1
0

9
1
2
4

1
0
1
4
2
8

7
.9

5
.0

0
.9

0
.7

0
.2

1
6
.9

E
a
st

m
a
n

C
h

e
m

ic
a
l

1
1

5
2
8
4

9
8
4
3
2

9
.9

6
.4

1
.7

0
.6

0
.2

1
5
.1

D
u

k
e

E
n

e
rg

y
1
2

2
2

4
1
0

9
3
1
7
4

2
0
.3

1
4
.7

2
.9

1
.5

0
.3

9
.8

C
o
n

o
c
o
P

h
il
li

p
s

1
3

4
5

1
2
6
9

9
1
9
9
3

3
4
.7

1
9
.6

1
0
.4

2
.5

0
.9

1
5
.2

P
re

c
is

io
n

C
a
st

p
a
rt

s
1
4

2
9

1
9
5

8
7
5
0
0

1
5
.8

5
.0

5
.3

2
.7

0
.6

1
2
.8

A
lc

o
a

1
5

6
1

5
7
4

8
5
9
8
3

2
0
.3

1
1
.1

5
.2

1
.5

1
.2

1
1
.7

V
a
le

ro
E

n
e
rg

y
1
6

3
6

1
4
4
2

8
3
9
9
3

5
9
.9

3
8
.7

1
8
.3

1
.8

0
.5

1
9
.8

F
o
rd

M
o
to

r
1
7

3
5

4
4
4

7
5
3
6
0

2
4
.6

1
5
.4

5
.1

2
.0

0
.3

1
1
.2

G
e
n

e
ra

l
M

o
to

rs
1
8

4
5

6
6
2

7
3
2
4
8

2
9
.5

1
7
.9

7
.3

1
.7

0
.4

1
5
.6

G
o
o
d

y
e
a
r

1
9

2
7

2
1
1

6
7
6
3
2

2
7
.3

1
9
.1

4
.3

1
.6

0
.4

1
5
.7

E
.O

N
2
0

1
0

1
9
4

6
5
5
7
9

2
1
.6

1
7
.1

1
.8

1
.1

0
.2

1
3
.2

M
a
ts

u
sh

it
a

E
le

c
tr

ic
In

d
l

2
1

4
1
8

6
5
3
4
6

5
4
.6

4
8
.1

3
.6

1
.4

0
.3

1
3
.1

F
re

e
p

o
rt

-M
c
M

o
ra

n
C

o
p

p
e
r

&
G

o
ld

2
2

1
8

1
6
8

6
3
9
1
1

6
2
.1

2
.9

5
7
.1

0
.5

1
.6

1
4
.8

A
p

o
ll
o

M
g
t.

(H
e
x
io

n
S

p
e
c
ia

lt
y

C
h

e
m

ic
a
ls

)
2
3

3
5

4
2
3

6
3
8
8
0

4
0
.2

1
4
.9

2
1
.9

2
.1

0
.6

1
3
.3

A
v
e
ry

D
e
n

n
is

o
n

2
4

1
3

1
0
2

6
2
7
4
0

3
7
.7

8
.3

1
4
.4

1
2
.7

0
.2

9
.7

B
A

S
F

2
5

4
5

6
0
3

6
0
9
8
4

3
1
.9

2
4
.5

4
.3

1
.1

0
.3

1
5
.9

O
w

e
n

s
C

o
rn

in
g

2
6

3
7

1
4
3

5
9
6
0
9

4
2
.6

1
4
.2

2
2
.0

4
.4

0
.5

1
4
.2

D
o
m

in
io

n
R

e
so

u
rc

e
s

2
7

1
9

1
9
6

5
8
6
4
2

2
9
.3

2
1
.4

3
.5

2
.2

0
.3

1
1
.3

A
ll
e
g
h

e
n
y

T
e
ch

n
o
lo

g
ie

s
2
8

2
9

1
6
8

5
8
3
7
5

8
.3

5
.2

1
.2

0
.6

0
.2

1
3
.1

B
P

2
9

5
8

1
2
7
1

5
4
3
3
6

5
4
.7

1
6
.9

3
0
.9

5
.4

0
.7

1
6
.2

H
o
n

e
y
w

e
ll

In
te

rn
a
ti

o
n

a
l

3
0

5
7

4
1
1

5
0
4
1
7

4
2
.1

3
0
.3

8
.8

1
.9

0
.3

1
5
.8

In
te

rn
a
ti

o
n

a
l

P
a
p

e
r

3
1

5
2

6
0
8

4
9
3
8
5

3
0
.6

2
5
.5

2
.6

1
.0

0
.4

1
6
.2

A
sh

la
n

d
3
2

6
7

6
4
6

4
3
4
9
2

3
0
.7

2
0
.6

5
.9

1
.6

0
.3

1
8
.9

C
o
n

st
e
ll
a
ti

o
n

E
n

e
rg

y
3
3

1
4

1
0
8

4
2
9
7
2

3
5
.5

2
1
.5

1
0
.2

2
.1

0
.3

1
1
.2

P
u

b
li
c

S
e
rv

ic
e

E
n
te

rp
ri

se
G

ro
u

p
(P

S
E

G
)

3
4

9
9
7

4
1
7
7
3

5
7
.0

1
8
.2

2
6
.8

1
0
.1

0
.4

1
6
.5

A
E

S
3
5

1
4

1
9
1

3
9
7
8
9

2
9
.8

1
4
.0

1
3
.9

1
.2

0
.3

1
5
.1

P
ro

g
re

ss
E

n
e
rg

y
3
6

1
4

2
3
4

3
8
0
2
7

2
4
.0

1
2
.3

7
.7

2
.1

0
.6

1
1
.2

N
u

c
o
r

3
7

2
9

3
1
7

3
6
9
6
3

5
1
.3

4
6
.9

2
.6

0
.7

0
.3

2
1
.2

U
n

it
e
d

T
e
ch

n
o
lo

g
ie

s
3
8

4
2

1
5
0

3
6
5
2
6

3
0
.6

2
1
.7

5
.7

2
.0

0
.3

7
.6

T
im

k
e
n

3
9

1
5

7
9

3
6
0
4
7

1
7
.6

1
2
.9

1
.1

0
.5

0
.4

1
7
.4

B
e
rk

sh
ir

e
H

a
th

a
w

a
y

4
0

6
2

4
1
9

3
5
2
8
5

3
7
.8

2
4
.3

1
0
.1

1
.5

0
.7

1
3
.2

S
P

X
4
1

1
2

4
9

3
4
5
5
9

3
9
.8

1
9
.6

1
4
.6

3
.2

0
.5

1
1
.2

T
o
x
ic

1
0
0

F
ir

m
s

−
2
5
1
8

3
0
9
6
5

4
7
2
4
0
9
4

3
4
.2

1
9
.8

1
0
.5

2
.1

0
.5

1
5
.2

A
ll

F
ir

m
s

−
1
0
2
6
3
6

1
6
4
7
0

1
4
5
7
6
9
8
2

3
4
.8

1
8
.1

1
2
.6

2
.2

0
.6

1
5
.3

U
S

P
o
p

u
la

ti
o
n

−
−

−
−

3
1
.8

1
1
.8

1
3
.7

3
.7

0
.7

1
2
.9

24



A
p

p
e
n

d
ix

T
a
b

le
1
,

c
o
n
ti

n
u

e
d

.
M

in
o
ri

ty
a
n

d
P

o
v
e
rt

y
S

h
a
re

s
o
f

A
ir

b
o
rn

e
H

u
m

a
n

H
e
a
lt

h
R

is
k
:

T
o
x
ic

1
0
0

C
o
rp

o
ra

ti
o
n

s

T
o
x
ic

1
0
0

R
S

E
I

M
in

o
ri

ty
B

la
ck

H
is

p
a
n

ic
A

si
a
n

/
P

a
c
ifi

c
N

a
t.

A
m

.
P

o
o
r

R
a
n

k
F

a
c
il
it

ie
s

R
e
le

a
se

s
S

c
o
re

S
h

a
re

S
h

a
re

S
h

a
re

S
h

a
re

S
h

a
re

S
h

a
re

R
o
y
a
l

D
u

tc
h

S
h

e
ll

4
2

1
9

6
0
9

3
4
5
5
6

4
3
.5

1
7
.3

2
0
.4

3
.8

0
.7

1
3
.8

S
o
u

th
e
rn

C
o

4
3

2
2

3
0
6

3
3
5
7
7

3
3
.6

2
6
.2

4
.2

1
.7

0
.4

1
2
.5

A
ll
e
g
h

e
n
y

E
n

e
rg

y
4
4

9
1
5
9

3
1
5
3
9

1
0
.2

7
.1

0
.8

1
.0

0
.2

1
4
.1

A
m

e
ri

c
a
n

E
le

c
tr

ic
4
5

2
0

5
2
4

3
1
3
6
4

9
.3

5
.7

1
.2

0
.7

0
.4

1
2
.4

R
e
li
a
n
t

E
n

e
rg

y
4
6

1
5

2
6
0

3
0
8
2
1

1
4
.0

8
.1

3
.5

1
.2

0
.2

1
0
.7

B
o
e
in

g
4
7

1
2

1
1
3

3
0
4
5
3

3
3
.7

1
2
.3

1
1
.1

6
.1

1
.3

1
3
.6

G
e
n

e
ra

l
D

y
n

a
m

ic
s

4
8

1
6

6
7

3
0
3
3
7

6
9
.0

1
1
.1

4
9
.1

6
.7

1
.0

2
0
.9

O
c
c
id

e
n
ta

l
P

e
tr

o
le

u
m

4
9

2
1

3
9
1

3
0
1
6
7

4
3
.6

3
0
.8

9
.7

1
.6

0
.4

1
6
.9

K
e
y
S

p
a
n

5
0

4
4
0

2
9
0
0
8

5
3
.7

1
8
.2

2
4
.7

9
.1

0
.5

1
7
.8

L
y
o
n

d
e
ll

C
h

e
m

ic
a
l

5
1

2
5

5
0
1

2
8
5
9
1

3
3
.6

1
1
.8

1
8
.5

1
.9

0
.3

1
4
.9

S
u

n
o
c
o

5
2

4
0

7
7
4

2
7
8
5
1

3
3
.5

2
2
.2

6
.1

3
.6

0
.3

1
6
.6

A
n

h
e
u

se
r-

B
u

sc
h

C
o
s

5
3

2
1

7
9

2
7
0
3
2

4
1
.0

3
0
.1

6
.5

2
.4

0
.4

1
6
.7

B
a
ll

5
4

3
0

1
8
4

2
5
7
0
9

3
8
.5

1
1
.3

2
1
.4

4
.1

0
.6

1
4
.8

D
e
e
re

&
C

o
5
5

1
0

6
7

2
5
3
4
6

1
9
.9

6
.8

1
0
.2

1
.1

0
.4

1
5
.6

P
ro

c
te

r
&

G
a
m

b
le

5
6

2
3

1
0
8

2
5
2
3
8

4
1
.2

3
6
.6

2
.4

1
.1

0
.2

1
6
.1

T
e
so

ro
5
7

8
3
6
1

2
4
7
0
8

2
4
.6

2
.6

1
1
.6

5
.9

1
.8

1
0
.0

T
e
m

p
le

-I
n

la
n

d
5
8

1
9

1
2
0

2
4
5
3
7

4
7
.0

2
4
.8

2
1
.2

0
.5

0
.4

2
0
.1

P
fi

z
e
r

5
9

1
7

2
3
1

2
4
5
0
8

3
8
.3

1
9
.5

1
3
.9

2
.5

0
.5

1
9
.8

R
o
w

a
n

C
o
s.

6
0

2
2
1

2
4
3
8
9

4
6
.2

3
0
.3

1
3
.6

0
.7

0
.5

2
1
.6

L
e
g
g
e
tt

&
P

la
tt

6
1

3
6

6
9

2
3
8
7
0

2
8
.2

5
.5

1
8
.6

1
.8

1
.0

1
2
.6

N
o
rt

h
ro

p
G

ru
m

m
a
n

6
2

1
4

8
7

2
3
7
9
8

5
6
.6

4
9
.8

3
.3

1
.8

0
.4

2
2
.6

W
e
y
e
rh

a
e
u

se
r

6
3

4
9

4
7
6

2
2
7
0
8

2
3
.0

1
5
.1

4
.0

1
.1

1
.1

1
7
.1

R
o
h

m
a
n

d
H

a
a
s

6
4

3
7

5
8
4

2
2
4
8
9

4
0
.9

1
5
.1

2
1
.4

3
.1

0
.4

1
6
.5

T
y
c
o

In
te

rn
a
ti

o
n

a
l

6
5

2
9

2
1
5

2
2
1
1
5

3
2
.7

1
6
.6

1
0
.6

3
.0

0
.7

9
.3

T
e
re

x
6
6

1
1

3
1

2
1
7
3
0

1
7
.3

4
.9

4
.6

4
.4

0
.6

9
.4

C
o
rn

in
g

6
7

6
2
6

2
0
9
4
2

1
7
.6

1
2
.6

2
.4

1
.2

0
.3

1
2
.6

E
x
e
lo

n
6
8

5
5
3

2
0
8
1
1

3
3
.6

2
4
.2

4
.9

3
.3

0
.2

1
3
.6

F
o
rt

u
n

e
B

ra
n

d
s

6
9

2
2

1
0
3

2
0
5
8
3

1
9
.5

8
.0

9
.4

0
.8

0
.5

8
.0

F
ir

st
E

n
e
rg

y
7
0

7
1
5
8

2
0
4
4
1

1
6
.8

1
2
.7

1
.7

1
.1

0
.1

1
0
.0

S
u

n
c
o
r

E
n

e
rg

y
7
1

1
3
5

2
0
3
7
8

4
5
.3

6
.9

3
3
.6

2
.5

1
.3

1
2
.9

C
ro

w
n

H
o
ld

in
g
s

7
2

2
3

1
3
7

1
9
4
4
7

3
0
.5

8
.0

1
7
.9

3
.6

0
.5

1
4
.3

M
a
sc

o
7
3

3
4

1
4
8

1
8
5
7
2

6
.7

1
.3

2
.8

1
.4

0
.4

1
2
.0

T
h
y
ss

e
n

K
ru

p
p

G
ro

u
p

7
4

1
6

1
3
0

1
8
1
3
3

2
1
.7

1
2
.0

7
.3

1
.2

0
.5

1
2
.1

T
e
x
tr

o
n

7
5

1
3

6
9

1
7
4
4
3

3
3
.6

2
4
.5

4
.9

1
.6

0
.7

1
3
.6

S
o
n
y

7
6

6
3
6

1
6
4
2
6

1
2
.5

7
.4

2
.1

2
.0

0
.2

5
.3

M
ir

a
n
t

7
7

9
1
3
8

1
6
3
3
7

4
2
.4

2
4
.9

1
0
.6

4
.6

0
.4

9
.2

R
A

G
7
8

3
1

2
5
2

1
6
0
8
0

5
2
.9

4
5
.6

4
.2

1
.5

0
.5

1
8
.4

A
lc

a
n

7
9

1
1

5
1

1
5
2
3
1

1
0
.8

6
.6

2
.2

0
.6

0
.2

1
2
.1

H
u

n
ts

m
a
n

8
0

1
7

2
8
0

1
5
1
1
9

4
7
.7

3
5
.0

9
.3

2
.2

0
.4

2
0
.4

B
ri

d
g
e
st

o
n

e
8
1

3
0

1
5
5

1
4
9
5
2

1
5
.9

8
.7

4
.0

1
.5

0
.4

1
0
.1

D
a
n

a
h

e
r

8
2

2
2

4
6

1
4
6
2
1

2
3
.9

3
.9

1
5
.8

2
.1

0
.9

1
5
.7

T
o
x
ic

1
0
0

F
ir

m
s

−
2
5
1
8

3
0
9
6
5

4
7
2
4
0
9
4

3
4
.2

1
9
.8

1
0
.5

2
.1

0
.5

1
5
.2

A
ll

F
ir

m
s

−
1
0
2
6
3
6

1
6
4
7
0

1
4
5
7
6
9
8
2

3
4
.8

1
8
.1

1
2
.6

2
.2

0
.6

1
5
.3

U
S

P
o
p

u
la

ti
o
n

−
−

−
−

3
1
.8

1
1
.8

1
3
.7

3
.7

0
.7

1
2
.9

25



A
p

p
e
n

d
ix

T
a
b

le
1
,

c
o
n
ti

n
u

e
d

.
M

in
o
ri

ty
a
n

d
P

o
v
e
rt

y
S

h
a
re

s
o
f

A
ir

b
o
rn

e
H

u
m

a
n

H
e
a
lt

h
R

is
k
:

T
o
x
ic

1
0
0

C
o
rp

o
ra

ti
o
n

s

T
o
x
ic

1
0
0

R
S

E
I

M
in

o
ri

ty
B

la
ck

H
is

p
a
n

ic
A

si
a
n

/
P

a
c
ifi

c
N

a
t.

A
m

.
P

o
o
r

R
a
n

k
F

a
c
il
it

ie
s

R
e
le

a
se

s
S

c
o
re

S
h

a
re

S
h

a
re

S
h

a
re

S
h

a
re

S
h

a
re

S
h

a
re

P
P

G
In

d
u

st
ri

e
s

8
3

3
0

4
9
6

1
4
3
0
0

2
3
.2

1
6
.7

3
.9

1
.1

0
.3

1
3
.0

H
e
ss

8
4

2
4

4
5
7

1
3
6
8
7

6
6
.5

1
5
.6

4
7
.6

4
.9

0
.3

2
6
.4

A
k
z
o

N
o
b

e
l

8
5

2
7

3
7
1

1
3
4
5
3

5
8
.6

4
4
.4

1
0
.4

2
.4

0
.3

2
5
.2

D
y
n

e
g
y

In
c
.

8
6

7
1
0
7

1
3
4
3
9

2
5
.6

1
3
.2

8
.9

2
.1

0
.3

1
0
.1

F
e
d

e
ra

l-
M

o
g
u

l
8
7

2
5

1
1
8

1
3
4
3
5

2
8
.0

2
1
.5

3
.5

1
.3

0
.3

1
3
.6

S
ta

n
le

y
W

o
rk

s
8
8

8
3
0

1
3
1
9
6

3
2
.1

2
3
.3

5
.7

1
.7

0
.4

1
0
.2

K
o
m

a
ts

u
8
9

2
4

1
3
1
3
2

3
0
.9

2
3
.2

4
.0

1
.0

0
.3

1
9
.2

S
a
in

t-
G

o
b

a
in

9
0

5
5

1
5
9

1
3
0
1
2

3
8
.6

2
3
.5

1
0
.2

3
.0

0
.6

1
6
.7

P
P

L
9
1

4
8
3

1
2
9
7
2

1
1
.6

4
.3

4
.6

1
.6

0
.2

8
.0

C
a
te

rp
il
la

r
9
2

1
3

5
6

1
2
9
2
4

2
4
.2

1
1
.9

8
.6

1
.7

0
.2

1
1
.0

S
m

u
rfi

t-
S

to
n

e
C

o
n
ta

in
e
r

9
3

3
0

2
4
4

1
2
8
6
8

2
9
.9

2
3
.1

3
.1

1
.6

0
.7

1
2
.0

S
ie

m
e
n

s
9
4

2
2

6
6

1
2
6
4
9

3
2
.8

1
8
.3

1
0
.5

2
.1

0
.4

1
2
.8

M
e
a
d

W
e
st

v
a
c
o

9
5

1
0

2
1
4

1
2
4
6
5

4
0
.9

3
4
.0

4
.0

1
.4

0
.4

1
8
.3

M
a
ra

th
o
n

O
il

9
6

3
7

7
0
5

1
2
4
5
4

3
3
.0

1
6
.3

1
2
.9

1
.9

0
.5

1
4
.3

E
m

e
rs

o
n

E
le

c
tr

ic
9
7

3
9

1
1
0

1
2
2
5
8

1
3
.1

7
.2

3
.7

0
.9

0
.3

1
5
.1

N
o
rt

h
e
a
st

U
ti

li
ti

e
s

9
8

5
8
4

1
1
1
1
5

1
1
.7

1
.4

5
.0

1
.4

3
.1

7
.9

N
a
ti

o
n

a
l

O
il
w

e
ll

V
a
rc

o
9
9

7
2
5

1
1
0
4
2

7
8
.0

2
2
.3

5
3
.0

2
.0

0
.7

2
6
.5

D
a
n

a
1
0
0

1
8

4
9

1
0
6
3
8

3
6
.2

2
9
.4

5
.3

0
.4

0
.2

1
7
.6

C
h

e
v
ro

n
1
0
1

4
8

9
8
4

1
0
5
0
5

4
5
.4

1
7
.1

1
7
.0

8
.3

0
.4

1
3
.7

T
o
x
ic

1
0
0

F
ir

m
s

−
2
5
1
8

3
0
9
6
5

4
7
2
4
0
9
4

3
4
.2

1
9
.8

1
0
.5

2
.1

0
.5

1
5
.2

A
ll

F
ir

m
s

−
1
0
2
6
3
6

1
6
4
7
0

1
4
5
7
6
9
8
2

3
4
.8

1
8
.1

1
2
.6

2
.2

0
.6

1
5
.3

U
S

P
o
p

u
la

ti
o
n

−
−

−
−

3
1
.8

1
1
.8

1
3
.7

3
.7

0
.7

1
2
.9

26


	Introduction
	Data and Methods
	The RSEI project
	The RSEI Project and Public-Release Data
	The RSEI Geographic Microdata (RSEI-GM)

	Census of Population & Housing: The Spatial Join 
	Corporation-facility matching

	A Measure of Corporate Environmental Justice Performance
	Measuring group shares of human health risk
	Results
	Environmental justice performance at the facility level

	Best and worst ``in class'' rankings
	Total Human Health Impact and CEJP
	Conclusions