key: cord-1012763-nfdshuqx authors: Doughty, David C.; Hill, Steven C.; Mackowski, Daniel W. title: Viruses such as SARS-CoV-2 can be partially shielded from UV radiation when in particles generated by sneezing or coughing: Numerical simulations date: 2020-12-24 journal: J Quant Spectrosc Radiat Transf DOI: 10.1016/j.jqsrt.2020.107489 sha: bb2ecc91268326de69b4c06a976664dd41d23929 doc_id: 1012763 cord_uid: nfdshuqx UV radiation can inactivate viruses such as SARS-CoV-2. However, designing effective UV germicidal irradiation (UVGI) systems can be difficult because the effects of dried respiratory droplets and other fomites on UV light intensities are poorly understood. Numerical modeling of UV intensities inside virus-containing particles on surfaces can increase understanding of these possible reductions in UV intensity. We model UV intensities within spherical approximations of virions randomly positioned within spherical particles. The model virions and dried particles have sizes and optical properties to approximate SARS-CoV-2 and dried particles formed from respiratory droplets, respectively. In 1-, 5- and 9-µm diameter particles on a surface, illuminated by 260-nm UV light from a direction perpendicular to the surface, 0%, 10% and 18% (respectively) of simulated virions are exposed to intensities less than 1/100(th) of intensities in individually exposed virions (i.e., they are partially shielded). Even for 302-nm light (simulating sunlight), where absorption is small, 0% and 11% of virions in 1- and 9-µm particles have exposures 1/100(th) those of individually exposed virions. Shielding is small to negligible in sub-micron particles. Results show that shielding of virions in a particle can be reduced by illuminating a particle either from multiple widely separated incident directions, or by illuminating a particle rotating in air for a time sufficient to rotate through enough orientations. Because highly UV-reflective paints and surfaces can increase the angular ranges of illumination and the intensities within particles, they appear likely to be useful for reducing shielding of virions embedded within particles. Viruses such as influenza, measles, smallpox, SARS and some noroviruses can be transmitted via particles in the air. Improved methods to reduce the transmission of viruses are needed. Ultraviolet (UV) light can inactivate SARS-CoV-2 [ 58 , 67 , 68 ] and other viruses [31, 32, [62] [63] [64] 71] , and thereby help reduce transmission rates [ 1 , 46 ] . Solar UV radiation near the Earth's surface, primarily UVB at 280-315 nm, can inactivate SARS-CoV-2 [ 58 , 67 ] and other microbes [61] . UVC (200-280 nm) is common for germicidal applications [ 4 , 14 , 16 , 32 , 35 , 59 , 76 ] . Viruses may occur within droplets (liquid particles of any size) expelled from the upper or lower respiratory tract [ 37 , 47 , 49 , 66 ] . These droplets can range in size from submicron to greater than 10 * Correspondence author. E-mail address: david.c.doughty2.civ@mail.mil (D.C. Doughty). μm in normal breathing and speaking [48] to 10 0 0 μm in sneezing or coughing [ 3 , 7 , 10 , 17 ] . Such liquid particles tend to lose water rapidly under subsaturated conditions, with evaporation likely occurring in less than 0.8 s for liquid particles with diameters < 20 μm [48] . The resulting dried aerosol particles can range in size from submicron [39] to greater than 20 μm. At a relative humidity (RH) of less than 50% they can dry into somewhat spherical particles, at least for sizes smaller than 25 μm [75] . In using reported size distributions of droplets and particles of dried droplets it is useful to note the ranges of sizes measurable with the instrumentation, whether the humidity and time before measurement resulted in droplets or dried droplets, and whether the size distributions are given as particle number or particle mass. The expelled droplets and dried particles may be inhaled or may land on surfaces and subsequently be transferred to nose, eyes, or mouth as part of the transmission of disease. Some viruses including SARS-CoV-2 can remain pathogenic in Fig. 1 . Illustration of optical features related to shielding of microbes such as viruses in particles from UV light. The material surrounding the particles is air. (a) Refractive shielding in a non-spherical particle. (b) Refractive and absorptive shielding in a spherical particle. If the virions are 100 nm diameter and the drawing is to scale, the large sphere is approximately 2 μm diameter. (c) Decrease in intensity with distance into a medium as a function of penetration depth for δ similar to those used in this paper. aerosol particles, either in air [ 45 , 67 ] or after landing on a surface [ 52, 58, 65, 67, 72] . Materials that were initially deposited from air may be reaerosolized (resuspended) [ 12 , 29 , 33 , 36 , 40 , 53 , 56 , 57 ] . Viruses and other microbes not initially deposited from air may be aerosolized (suspended in air) by toilet flushing, wind-gusts, waterdrop splashing, walking, or mechanical processes [ 15 , 26-28 , 38 , 70 ] . Some relevant surfaces for virus transmission include those in restaurants, restrooms, healthcare facilities, and personal protective equipment, including facemasks [ 12 , 77 ] . There are many uncertainties relating to the relative importance of different routes of transmission of viral diseases, including COVID-19. The relative importance of these modes depends upon the virus species, and can depend on factors such as the size distributions of virus-containing particles [8, 66] , the locations in infected persons where their viral loads are highest [78] , airflows [7] , humidity [45] , and behaviors of the relevant persons. In the case of SARS-CoV-2, although many questions remain unanswered, there is considerable interest in using UV to inactivate virions on surfaces [58] , and in air [5, 14, 20, 50] . A microbe in a particle may be partially shielded from UV by other materials in the particle [18, 30, 51] . This shielding may result in microbes remaining infectious in particles even when the particles are exposed to sufficient UV light to inactivate the microbes when exposed individually. Such shielding can make germicidal UV more difficult in settings where microbes are in particles. An improved understanding of how virions in particles can be shielded from UV light could help in effectively using UV to deactivate SARS-CoV-2 and other microbes. Optical phenomena affecting shielding of viruses from UV include the following (see Fig. 1 ): i) Absorption of UV causes the intensity to decrease as it travels into the particle and so reduces the intensity of UV reaching the virion. ii) Refraction of UV at a surface of a particle can direct light away from a virion; the importance of refraction depends upon the shape of the particle, the angle of the incident UV light with respect to the orientation of the particle, and on the optical properties of the particle and the material outside the particle. iii) Reflection at the outer surface of a particle can reduce the UV entering or exiting a particle; in inhomogeneous particles it can occur at surfaces separating regions within the particle. iv) Diffraction and scattering can increase UV intensities in regions which may otherwise be dark, in a ray optics approximation, because of refraction and absorption. Models of the UV intensities in particles containing viruses can be useful in understanding UV inactivation and in improving UV decontamination systems. Valid models for the UV intensity within each virion can be combined with measured inactivation data to predict the numbers of virions likely to be inactivated within a particle. Validated models can predict results for large numbers of potential experiments that are impractical to perform in the laboratory or the field. Thus, such models can be essential tools for identification of decontamination techniques most appropriate for further testing. In this paper we calculate the UV intensities in 100-nmdiameter spherical particles (approximating SARS-CoV-2 virions) located within an encompassing spherical particle simulating dried saliva or other airway fluid. The encompassing particles are on a surface or in air. The complex refractive index (m = m r + i m i ) for the dried airway fluids and for SARS-CoV-2 virions are estimated using compositions of dried fluids and virions extracted from the literature and the optical properties of the various components similar to that in Hill et al. [ 23 , 24 ] . Both the simulated virions and dried fluid particles are homogeneous in the simulations run here. The UV intensities within the virions within the dried droplets in this model problem are calculated using the Multi-Sphere T-Matrix (MSTM) method [ 41 , 43 , 44 ] . The MSTM provides an exact solution to the electromagnetic field equations (Maxwell's equations) for problems which include non-overlapping spheres within spheres, with or without a planar surface. The particles are illuminated by a UV plane wave at 260 nm or 302 nm. UV intensities within virions are calculated for three different encompassing particle sizes, plus the naked virion, as well as four different imaginary refractive indices for the encompassing fluid. Typically, illumination is from normally incident light, but in some cases illumination is from as many as five different directions or equally from all directions. These calculations can help in understanding the shielding of virions from UV, including: the wavelength-dependence of shielding; increases in shielding in larger sized particles; and reductions in shielding in particles illuminated from multiple angles. Concentrations of components of saliva used here are selected to be representative of values reported by several sources [ 6 , 11 , 73 , 74 ] . The concentrations provided in Table 1 .2 in [11] (a compilation of 20 sources) are used for inorganic electrolytes (Na + , K + , Mg 2 + , Ca 2 + , Cl − , PO 4 3 − , HCO 3 − , SCN − , and F − ); non-UV-absorbing small molecules (glucose, lactate, lipids, urea, and ammonia); proteins and free amino acids; and the mucin glycoproteins. The concentration of protein used is 1.63 mg/ml. The combined concentration of mucins (MUC5B and MUC7) is 1.27 g/L, a concentration which includes both the amino acids and the carbohydrate of these glycoproteins. Typical mass fractions of airway mucin are 25% protein and 75% carbohydrate. Using these values, we calculated concentrations of carbohydrate in the mucins are 0.75 × 1.27 g/L = 0.95 g/L. Reported concentrations of DNA in saliva range from approximately 0.01 to 0.28 mg/ml [55] . The DNA concentration here is assumed here to be 0.12 mg/ml. Concentrations of RNA are assumed to be equal to those of DNA (0.12 mg/ml). We know of no reported measurements of non-viral RNA in saliva or nasal fluids. However, we assume that the DNA in these fluids arise from cells. Cells (human or bacterial) typically have several times as much RNA as DNA [23] , and so the assumption of 0.12 mg/ml for RNA may be low. Hydrolysis of DNA or RNA by nucleases does not eliminate the UV absorption by the bases. The concentration of uric acid used is 0.024 mg/ml, in the range of values measured [ 2 , 19 ] . Peden et al. [54] demonstrate uric acid in nasal airway fluids. Each virion is assumed to be 100 nm in diameter, where the outer 5 nm is a lipid bilayer. The virus genome, ssRNA (29, 893 nucleotides, A = 8954, T = 9594, G = 5863, U = 5492) has a mass of 1.39 × 10 −17 g, which is only 0.22% of the virion mass. The mass of the virion not in RNA or lipid is assumed to be protein, although we suspect other small UV-light-absorbing molecules such as uric acid or NAD may be enclosed within the virion. The primary optical property needed for modeling the UV in particles is the complex refractive index, m = m r + im i . The imaginary part of m is defined as m i = λ/4 πδ, where λ is the free-space wavelength, and δ is the penetration depth, a key parameter useful in understanding shielding by absorption. If I(z) is the intensity (I) of a UV planewave at distance z in a homogeneous medium, the fraction of light remaining at z is I(z)/I 0 = e −z/ δ , where the in-tensity at z = 0 is I 0 , and δ is the distance at which the UV has decreased to 1/e ( = 0.368) of I 0 . Also, m i = λc ε/4 π , where c is the concentration of the absorbing material and ε is the molar absorption coefficient [25] , also termed absorptivity [22] [23] [24] , molar absorptivity, molar extinction coefficient or molar attenuation coefficient. The molar absorption coefficients of biological materials at the wavelengths used were estimated from the literature as described previously [22] [23] [24] . The density of the dried solids is estimated as a weighted average of the densities of materials in the droplet. Using the concentrations of materials within the droplet, and the density of the dried particle, the concentrations of the relevant materials in the dried droplet are calculated. The contribution of the j th material to the total m i of the dry particle, i.e., m i,j is then is calculated using the concentration (g/g) and the extinction coefficient for the material as described previously [ 23 , 24 ] . The total m i is the sum of the m i,j . The main UV-light-absorbing materials in the 260 to 302 nm range in airway fluids are tryptophan and tyrosine (primarily in proteins), nucleic acids, and uric acid [19] . At longer wavelengths the absorption by proteins, nucleic acids and uric acid tend to be so low that the penetration depths δ are many times larger than the diameter of most dried particles. In calculating the m i for virions, the average amino acid composition is taken as the average of all the amino acids specified by the genome. The different proteins are not weighted by their copy number or mass fraction mainly because we do not have values for these mass fractions. For the calculations of the UV absorbed by virions, each virion is assumed to be homogeneous. The code to calculate the m r and m i used here is similar to that described previously [22] [23] [24] . Droplets of airway fluids are assumed to be generated by sneezing or coughing. Their properties are assumed to be consistent with those of saliva or nasal fluids. The expelled droplets are assumed to dry into spherical particles; the dried particles of simulated saliva studied by Vejerano and Marr [75] appeared to be somewhat spherical, at least for particles smaller than 25 μm. The dissolved solids in saliva are assumed to be 6 mg/cm 3 (0.006 × 10 −12 g/ μm 3 ), in the range of reported values [11, 75] . We assume a density for the dry particle of 1.5 g/cm 3 (1.5 × 10 −12 g/ μm 3 ). For these values, droplets with diameters of 6.3, 31.5, and 56.7 μm, dry to particles with diameters of 1-, 5-and 9-μm respectively, the sizes studied here. Virions comprise at most a very small fraction of the mass of the solids in airway fluids. The concentrations of SARS-CoV-2 virions measured in COVID-19 patients and healthcare workers [78] ranged from 4 × 10 4 to 4 × 10 10 copies/mL in saliva and up to 5 × 10 9 copies/mL in nasal fluids. The mass of a 100 nm diameter virion having an assumed density of 1.2 g/mL is 6 × 10 −13 mg. The mass of 4 × 10 10 of these virions (highest number measured in 1 mL by Wyllie et al. [78] ) is 0.024 mg, i.e., 1/240 th the mass of the other solids in the typical saliva assumed here. For the properties described in the previous paragraph, the maximum average numbers of virions per dried 9-μm particle is 3680 and in a dried 5-μm particle is 630. For almost all the other cases reported by Wyllie et al. [78] , the concentration of virions is orders of magnitude smaller, and the majority of sneezed or coughed droplets resulting in dried particles in the 1-to 9-μm range would have no virions. The location of virions within dried droplets of airway fluids has not been measured, so far as we know. We assume the virions are randomly distributed throughout the dried respiratory droplet. The spatial distribution of virions in 3D within a 9-μm diameter sphere approximating a spherical particle of dried airway fluids. The color of each virion indicates the R i , the relative UV intensity within that virion, and is proportional to the rate of absorption of UV energy by that virion. The incident UV light propagates downward from the top of the page, in the z direction. The surface begins at z = 0. For all z < 0 and not inside the dried droplet the material is air. Results were calculated using the MSTM. The outer edge of the larger particle is not shown, but is just outside the outermost virion locations. The R i were calculated using 120 sets of 100 virions each. B: A slice through the center of the sphere including all virions with -0.5 < x center < 0.5 μm. In this paper the UV intensities in the spherical particles were calculated by solving the electromagnetic field equations (Maxwell's equations) for a number of homogeneous spheres, separate or included within other spheres, and with the potential of being in contact with a flat surface, all illuminated by one or more plane waves [ 41 , 43 , 44 ] . In the MSTM as used here, a plane wave with irradiance I o (or set of n plane waves with irradiance I o /n for each wave) illuminates either a naked virion or a spherical particle which contains a number of virions. The net rate of energy absorption by the i th virion is I o π a i 2 Q abs,i , where a i is the radius and Q abs,i is the absorption efficiency, each for the i th virion. The focus in this paper is on the absorption of UV energy by virions in the large particle relative to virions resting on (or very near, i.e., 10 nm) the surface. A main quantity illustrated here is the relative rate of absorption of UV energy of the i th virion, R i = Q abs,i / Q abs,single where Q abs,single is the absorption efficiency of an indi-vidual virion resting on the same surface. Because the diameters and m for all virions in a given simulation are identical, R i is the relative UV intensity within the i th virion. The illumination used in the calculations is unpolarized because sunlight and UV lamps are unpolarized. When multiple illumination angles of incidence are used, each R i is calculated for each virion for each angle of incidence with respect to a naked virion on the same surface illuminated with normally incident light. For each virion, R i from the different angles of incidence are averaged. Fig. 2 illustrates a 3D plot of 12,0 0 0 virions (calculated as 120 sets of 100 virions each) randomly positioned within a 9-μm sphere simulating a dried saliva particle. The 12,0 0 0 virions are used to illustrate the position-dependent variations in UV energy Table 1 For dried droplets of respiratory fluids, the approximated concentrations (mass%) of the main UV absorbing materials and contributions to the imaginary part of the refractive index (m i ) (total and percentage). The wavelengths used are in the top row. In the bottom three rows are the complex refractive index and the penetration (skin) depth. absorbed by the virions, not because a 9-μm particle is likely to carry such a large number of virions. A large number of virions are needed to represent the distribution well. The m r and m i used for the calculations are as shown in Table 1 for the dried saliva, and in Table 2 for the virions. The particle is present on a surface with m = 1.4 + i 0.0 0 01. The particle is illuminated with 260-nm light which propagates downward (from the top of the figure) in a direction normal (perpendicular) to the surface. The illumination is unpolarized for this normal-incidence case, and so the intensity distribution would be independent of the angle around the sphere axis aligned with the direction of wave propagation if the sphere were perfectly homogeneous. The virions are color coded according to R i , the relative rate of absorption of UV energy by the i th virion relative to an isolated virion on the same surface (see Section 2.4 ). Also, the lowest intensity regions, indicated by colors from turquoise to black, have UV absorption efficiencies that are over two orders of magnitude smaller than the UV absorption of an individual virion on a surface. In these figures, the shielded regions result from a combination of absorptive and refractive shielding. The highest intensities in Fig. 2 are at the top of the dried droplet (where the incident beam first encounters the particle), along a cone formed as the light is focused by the first illuminated surface of the encompassing sphere, and along an axis of the droplet in the direction of propagation of the wave (normal to the planar surface) which passes through the center of the sphere. The intensity of the cone increases as its radius decreases as it descends through the droplet and partially reflects internally from the droplet surface as visualized using geometrical optics [9] . The most shielding from UV occurs in the outer edge of the particle on the side away from the incident light. Virions at the center of the particle are negligibly shielded by refraction from UV. The sensitivity of the distributions of the R i to the numbers of virions in a dried particle was examined by calculating the R i for particles with 40 0 0, 30 0 0, 20 0 0, 10 0 0, 50 0, 250, 10 0, 50, 25, and 10 virions. Effects of changes in virion numbers on the distribution of R i calculated were below 0.5% until over 100 virions were used in a 9-μm dried droplet (Fig. S1 ) and 25 virions in a 5 μm dried droplet (Fig. S2 ). With either 260-or 302-nm illumination the extent of shielding decreases as particle size decreases (in moving in Fig. 3 from the top to the bottom panel in either column, or in moving from 3a to 3d or 3e to 3h in Table 1 ). For example, at 260 nm, in the 9-μm particle, 29.6% of virions have R i < 0.1 and 6.4% have R i < 0.001; in the 5-μm particle, 24.2% of virions have R i < 0.1 and 10% have R i < 0.01, but none have R i < 0.001; in the 1-μm particle over 31% of the virions have R i > 1.0, and 0.2% have R i < 0.1. In the limiting case of the 0.1 μm naked virion there is no shielding ( Table 3 ). In the panels on the right of Fig. 3 (d-g) with 302-nm illumination, the virions are less shielded from UV than at 260 nm, especially for the 5-and even more for the 9-μm particles. The differences between the extent of shielding at 260 nm vs 302 nm are primarily because the penetration depth is several times larger in the case of 302 nm illumination. The lower m r at 302 nm also contributes to the reduction in shielding, but contributes less than does the decrease in m i . Table 1 for 302 and 260 nm respectively. The δ in the top panel of Fig. 3 is six times the δ given in Table 1 for 302 nm. The bottom panel has a δ of ½ the δ estimated for 260 nm (in Table 1 ). In moving from panel a) to d) the center value of log(R i ) of the bin with the highest number of virions decreases as follows: -0.05, -0.15, -0.35, -0.85. In the case with the lowest m i 58.7% of the virions have R i greater than 0.5, and none have R i < 0.001. As the m i increases, R i decreases, and for the most absorbing case, 11.8% of virions have R i < 0.001 and 1.9% have R i < 0.0 0 01 ( Table 3 ). The 9-μm particles are illustrated because the shielding is largest in these particles, as seen in Fig. 3 . for three incident angles ( β) relative to the vertical, also termed the zenith angle. In Fig. 5 a-c, β = 0 °, 40 °and 80 °respectively. For these angles, the percentage of virions with R i < 0.1, R i < 0.01, and R i < 0.001 is approximately 30%, 15%, and 5% respectively ( Table 3 ) . However, although there are no virions with R i below 0.0 0 01 at an incident angle of zero degrees, at 80 °, approximately 1% of the virions had relative intensities below 0.0 0 01. Also, when β = 80 °there are a higher number of virions with R i > 0.8 ( Table 3 ). The 9-μm particles are illustrated for the different angle analysis because the shielding is largest in these particles, as in Fig. 3 . Fig. 6 illustrates normalized distributions of numbers of virions in R i bins for virions in a 9-μm particle on a surface illuminated by one-to five-planewaves. The illumination could be simultaneous or sequential: the resulting total UV intensities within virions are identical because the UV light source is not coherent. In Fig. 6 a the illumination is from above the sphere ( β = 0 °). In Fig. 6 b the angles Table 3 Percentage of virions below relative intensity of 1, 0.8, 0.5, 0.1, 0.01, 0.001, 0.0 0 01. Wavelength ( λ), m i , angle, orientation, and number of particles are shown. The wavelength is in units of nm, diameter is in units of microns. For orientation, "F" means Fixed, "All" means averaged over all orientations, "S" means on a surface, and "A" means in air. The percentages are shown in green in the table. ( β, α) are (0 °, 0 °) and (40 °, 0 °) (the azimuthal angle is α). In Fig. 6 c the two incident waves are defined by angles (0 °, 0 °) and (80 °, 0 °). In Fig. 6 d the two incident waves are given by (80 °, 0 °) and (80 °, 180 °). In each of these four cases ((a) to (d)), between 29.6% and 12.4% of virions have R i below 0.1 ( Table 3 ) , with the percentage with R i below 0.1 decreasing as the angle between the two beams increases in Fig. 6b-d. In each of the last three panels, three or more incident UV waves are used and the percentage of particles with R i > 0.1 in-creases as additional beams are added. In Fig. 6 e four UV waves are incident, from angles (80 °, 0 °), (80 °, 90 °), (80 °, 180 °) and (80 °, 270 °); 8.5% of virions have R i < 0.1; and the minimum R i is 0.0 0 02. In Fig. 6 f, three incident waves are used: two planewaves propagating primarily toward each other (at angles (80 °, 0 °) and (80 °, 180 °)), and the third wave traveling perpendicular to the surface. In this case, 10.3% of particles have R i < 0.1, and the minimum R i is 0.004. In Fig. 6 g the particle is illuminated by five planewaves: one is normally incident; the other four have β= 80 °and azimuthal an- For an objective of illuminating every virion in such particles with at least some desired UV intensity, these results suggest that illuminating with multiple widely-separated waves as illustrated in Fig. 6 d and e, and especially in Fig. 6f and g, could provide a way to achieve that goal with lower total UV energy than needed for illumination with only one or two beams separated by ≤ 80 °. [42, 43] . Also shown in Fig. 7 are the UV distributions for the fixed-orientation cases (shown with thin lines), on a surface and in air. In the particles averaged over all orientations, no 5-or 9-μm particles have R i < 0.1. In contrast, the fixed-orientation 5-μm particles have 8.6 and 10% of virions with R i < 0.01 (in air and on the surface, respectively). The 9-μm particles have 16.6 and 17.5% of virions with R i < 0.01 (in air and on surface, respectively) and have 6.7 and 6.4% of virions with R i < 0.001 (see Table 3 ). That is, for an airborne UV-illuminated 9-μm particle with the properties used here, which rotates through enough angles such that it is approximately illuminated uniformly by UV light from all directions, the best shielded virions are still exposed to a UV intensity approximately 1/7 th of that of a clean individual virion. If that same 9-μm particle were held on a surface, or illuminated for such a short time that it could change orientation very little, then approximately 17% of the virions are shielded so that their exposure to UV is less than 1/100 th of that of a clean individual virion. Airflows are turbulent in most situations where UV light is used to inactivate viruses in air. Particle orientation with respect to a UV light source can vary by "spinning" (i.e., rotating about a particle axis), or by "tumbling" (i.e., rotation of the axis of the particle), or by following the airflow. Particles undergo Brownian translational and rotational diffusion [13] even in a small closed container. The extent to which the UV in a particle is equivalent to the orientation-averaged results depends upon the airflows (including turbulence), Brownian rotational diffusion, particle size, time of exposure, and the position(s) and spatial extent(s) of sources of UV light. For a sufficiently short illumination time and slow enough particle rotation, particle rotation during illumination is negligible and the particle is essentially illuminated from one angle, as if it were "fixed in air". a) Shielding increases with particle diameter as illustrated in Fig. 3 for 0.1, 1-, 5-, and 9-μm diameter particles. This increase occurs both with 260 and 302 nm light. Shielding of virions within the 1-μm particles is small compared with that in larger particles: only 0.2% of the 1-μm particles at 260 nm have R i < 0.1. Absorptive shielding tends to become more important with increasing size because, on average, the UV energy must travel further through the particle to reach the virions, and so the light is more strongly attenuated prior to reaching a given virion. b) Shielding of virions can be very significant even in weakly absorbing particles. Even when the penetration depth is 6.7 times greater than the particle diameter ( Fig. 4 a) , 3.5% of the particles have R i < 0.01 and 22.8% have R i < 0.1. At such large ratios of δ/d the shielding is largely refractive. As the penetration depth of the dried respiratory fluids decreases from 59.9 μm to 10.0, 2.8, and 1.4 μm, the percent of R i < 0.001 increases from 0.0 to 0.06, 6.4 and 11.8%, respectively. c) Shielding of virions from UV light occurs with both the germicidal (260 nm) and solar (302 nm) wavelengths studied. Such shielding tends to be more significant at 260 nm where biological materials are more absorbing. d) For virions in a sphere held in a fixed position, either in air or on a surface with m r = 1.4, the differences in the UV in the virions in these two cases is relatively small. This finding holds for both the 5-and 9-μm diameter particles illustrated. UV intensities within refractively shielded regions can be increased by illuminating the particles from widely separated angles ( Fig. 6 d-g) , in cases where such illumination is possible. Wideangle illumination can be achieved to varying degrees by using multiple UV light sources, and/or using movable or robotically controlled sources. Equal magnitude waves propagating in opposite directions have been used previously to increase the light intensities in the regions of lowest intensity in a sphere [21] Shielding of virions in particles illuminated from all directions or that rotate (spin and/or tumble) through all orientations is orders of magnitude smaller than in singly illuminated, fixedposition particles ( Fig. 7 ) . Absorptive shielding can still be significant in such cases. Whether or not an airborne particle of a certain size rotates through enough angles to have a only small amount of refractive shielding and a smaller effect of absorptive shielding depends on the particle size and shape, the illumination times, positions of the UV lights, and airflows (turbulent, laminar, circuitous or straight). Variations in compositions and morphologies of viruscontaining particles exist even for dried droplets of sneezed or coughed respiratory droplets. Estimating the m i of saliva or other respiratory fluids from reported compositions of such fluids is not trivial. No one source provides all the relevant concentrations. It is not sufficient to know only the concentrations of the UV-absorbing materials in saliva, which would be adequate for estimating the m i for the aqueous solution. The material for which the m i is needed is the dried droplet. In the dried droplet, the concentrations of the UVabsorbing material (and thus the m i ) depend upon the concentrations of all the materials in the dried droplet. The best source we know for concentrations (with error bars) of the materials in saliva is Edgar et al., [11] , especially Table 1 .2, including the papers cited for the values. However, that table does not include uric acid or nucleic acids (including DNA, RNA, or other several other UV absorbing materials such as NADH, nucleosides, or vitamins). In our estimates of concentrations and m i in Table 1 , for dried droplets of respiratory fluids, uric acid is responsible for 98% of the m i for saliva at 302 nm and 9.4% of the m i at 260 nm. DNA, RNA and any other nucleic acids are responsible for 82% of the m i at 260 nm. Because the DNA concentrations in saliva vary over a wide range (from 0.01 to 0.28 mg/ml, as measured by Poehls et al. [55] ), and there is little if any reason to think RNA and ribonucleoside concentrations vary less widely, the m i of dried particles of saliva appear likely to vary over large ranges. DNA and RNA in saliva occur primarily from breakdown of immune cells and bacteria. Cells tend to have several times more RNA than DNA, but once the cell is broken the RNA is more rapidly degraded. Thus, there is considerable uncertainty in the concentrations of chemical species in dried airway droplets. The aromatic amino acids that are responsible for 8.8% of m i at 260 nm ( Table 1 ) occur primarily in the protein fraction of mucins, and to a lesser extent in albumin, immunoglobulins, and enzymes such amylase and lysozyme. Different mucins and enzymes predominate in different parts of the airways. The different salivary glands secrete different mucins and enzymes, or different concentrations of these. Even for a single person the concentrations of different inor ganic ions, different mucins and other proteins, uric acid, DNA, etc., may depend upon hydration, exercise, odors, time of day and time since last drink or meal. The concentrations of various chemical species in airway fluids vary from person to person, as does the bacterial microbiome [2, 11, 19] . 6 . Numbers of virions in bins with the log(relative UV intensity) shown. Particle diameters are 9 μm. The wavelength of the incident UV light is 260 nm. Particles are on a surface with m = 1.4 + i 0.0 0 01. In (a) the UV light is incident perpendicular to the surface (blue). In (b) one UV wave is normal to the surface and the other is 40 °from the normal. In (c) one UV wave is normal to the surface and the other is 80 °from the normal. In (d) both waves are incident 80 °from the normal to the surface but the azimuthal angle is 0 °in one and 180 °in the other. In (e) four waves, all incident at 80 °from the normal, are used. They differ in having azimuthal angles of 0 °, 90 °, 180 °a nd 270 °. In (f), three incident UV waves are used, the two waves as in (d) but also with the normal-incidence wave of (a). In (g), five incident UV waves are used: the four waves as in (g) but also with the normal-incidence wave of (a). Each incident UV plane wave has the same intensity. To compute the intensities within virions the intensity for each angle of incidence is averaged. The area under each distribution is normalized to 1. The particles here were assumed to be very dry, as in very lowhumidity, desert environments. Vejerano and Marr [75] showed that as droplets of simulated saliva were exposed to lower RH, they lost water and decreased in size. For the particles modeled here, at least for water contents above some low level, higher RH would result in higher water contents of the dried particles. Such increased water contents and particle volumes would result in lower densities, lower concentrations of light-absorbing materials (g/g in the dried particle), and larger penetration depths. However, a variety of proteins at their lowest water contents (less than about 6 to 10%) increase in volume as the water is removed [69] . So, at the lower water fractions, 0 to possibly 10%, it is not clear whether the density would continue to increase the water decreases. Sirotkin et al. [69] , wrote about hydrating very dry proteins: "The hydration of charged and polar groups causes a decrease in volume." Saliva and other airway fluids are complex mixtures which contain multiple inorganic and organic ions, mucins, nucleic acids, etc. These solutes have many charged and polar groups. Thus, it is possible that at very low water contents, the density could decrease as water content decreases. Variations and uncertainties in the densities and compositions of the dried particles may be the largest sources of differences between the calculations illustrated here and any specific particle of dried respiratory fluids. To account for such variability the model results were calculated for additional m i which increased the range of penetration depths used from 2.8 to 10 μm ( Fig. 3 ) , to 1.4 to 59.9 μm ( Fig. 4 ) . While the actual composition of a real dried saliva drop might be different than the compositions used here, the results should be general enough to apply to some degree. Even though the variations in concentrations of materials measured in saliva and other airway fluids are not small, the absorptive and refractive shielding illustrated here are general phenomena useful for understanding how virions may be protected from UV radiation. shown. The distributions in solid bars are for intensities averaged over all orientations. Distributions shown by the blue lines are for the same particle in air, but in a single orientation. Distributions shown by the orange lines are for the same particle, but held on a surface (m r = 1.4) at a single orientation. In (a) the particle is 5-μm diameter. In (b) the particle is 9-μm diameter. The R i for the "Orientation Averaged" and "Fixed in Air" are both relative to a single virion in air. The R i for the "Fixed on Surface" are relative to a single virion on the same surface. The orientation-averaged simulations used in (a) 30 0 0 virions (30 runs of 100 virions for a 9-μm particle), and in (b) 10 0 0 particles (40 runs of 25 virions for a 5-μm particle). The area under the each distribution is normalized to 1. Actual dried particles of airway fluids containing virions are neither perfectly spherical nor optically homogeneous. For particles formed by drying droplets of simulated respiratory fluids (water, mucin, NaCl and DPPC) on a superhydrophobic surface, the particles with sizes similar to those modeled here were somewhat spherical [75] . In the larger dried droplets, crystals of mucin, NaCl, and DPPC formed, in some cases making the particles inhomogeneous and less spherical [75] . The use of four components (NaCl, mucin, DPPC and water) for the simulated saliva may be the reason for this crystallization into what appear to be somewhat pure materials, and the resulting nonsphericity. Human saliva, on the other hand, is more complex [ 2 , 11 , 19 , 54 , 55 ] as seen in Section 2.2 above. There are many different inorganic (Na + , K + , Mg 2 + , Ca 2 + , Cl − , PO 4 3 − , HCO 3 − , SCN − , F − ) electrolytes, organic acids (lactic and uric acids), glucose, amino acids, peptides, proteins, nucleic acids, etc. Also, DNA and RNA in saliva increase the viscosity. It is therefore not clear which materials, if any, crystalize as pure components when droplets of airway fluids dry, and therefore, whether this possible cause of nonsphericity and inhomogeneity is relevant in dried droplets of actual respiratory fluids. Although there are uncertainties about the shapes and homogeneities of dried droplets of airway fluids, some general comments about shielding in such particles can be made. First, as illustrated in the first panel of Fig. 1 , neither refractive nor absorptive shielding requires spherical particles. Second, given the complex-ity of airway fluids, it seems unlikely that differences in refractive index within the particle will be as large as those between pure NaCl and a typical pure protein. A small amount of inhomogeneity inside a spherical particle appears to have a small effect on the UV intensities within virions. For example, adding 90 randomly located virions to a 9 μm particle containing 10 virions resulted in changes in R i of the initial 10 virions ranging from 0.03% to -0.27% (Fig. S1) . Third, if the surface of a particle were sufficiently rough that it scattered the UV light in all directions as the light entered the particle, then, as can be envisioned using Fig. 1 a and b , refractive shielding could be far less than it would be in an otherwise identical particle with a smooth surface. A nonsphericity that could decrease shielding in particles with a large ratio of penetration depth to particle size, would be a highly inhomogeneous particle with rough surface, where the UV light is scattered in all directions. Fourth, inhomogenities such as large air pockets forming within droplets as they dry, or large cracks occurring as the particles shrink, may have large impacts on the UV intensity distribution. It is, however, difficult to see how a single air pocket or crack would eliminate the potential for refractive shielding, at least at some illumination angles, unless there were multiple cracks and the sides of them were rough. Also, air pockets or wide cracks could decrease absorptive shielding for some illumination angles. Fifth, the locations of the virions in particles are not known [75] . However, it is easy to imagine that as a droplet dries, and as water evaporates and leaves behind a more concentrated region near the droplet surface, the 100-nm virions may be more likely to diffuse more slowly toward center of the droplet (where the concentration of everything except water is lower) than do proteins and smaller molecules. If that is the case, and so if virions are more likely to occur in the outer fraction of the dried droplet, then the fraction of particles which can be refractively shielded is likely to be higher than indicated in the figures and in Table 3 . Fig. 2 shows that for a particle on a surface and a normally incident plane wave, the most shielded virions are near the outside of the particle. Even for δ = 2.84 μm and the 9-μm particle ( Fig 2 b) , virions within approximately 2 μm of the center point of the particle appear to have R i > 0.1. In the outer approximately 1.5 μm of the hemisphere closest to the surface, some particles are well-shielded. Thus, if the virions localize to the surface of the dried droplet as may be plausible, the overall shielding would likely increase for fixed particles on a surface. For inactivation of virions in particles on surfaces, the data in Fig 6 d-g and Table 3 suggest that multiple UV-light sources positioned to illuminate from widely varying angles can reduce shielding in supermicron particles. Similar reductions in shielding could be obtained using movable light sources. Highly UV reflective paint on walls and surfaces in a room [34, 59, 60] increase the total UV intensity illuminating particles, and can increase the UV intensities in otherwise shielded regions, partly by increasing the number of directions from which a particle is illuminated. For inactivation of particles in air, UV illumination of particles from many angles can be easier to achieve because particles can change their orientation with respect to the source(s) of UV illumination as they move through a UVGI system and can spin about an particle or tumble as the axis rotates. However the extent of rotation depends on the particle size, the time it is illuminated, the air flows, and the degree of turbulence. Brownian rotational diffusion decrease with particle size. To reduce the need for rotation of particles about their axis (in order to avoid shielding) UVGI systems that illuminate particles somewhat uniformly from all directions may be ideal. Alternatively, UVGI systems which illuminate from one direction, or directions separated by a not-large angle, may reduce shielding if they are designed so that even the largest particles have sufficient time to spin and tumble through a sufficiently wide range of angles as they flow through the system (and approximate the all-orientations results of Fig. 7 ) . In flow-through UVGI systems, filters which remove a high percentage of particles larger than, e.g., 5 μm, are common [32] . Such filters reduce the need to design UVGI systems to inactivate larger particles. Rotation of particles in turbulent air flowing through a UVGI or other system is a topic that appears to need further investigation. Virions in particles may be partially shielded from UV. Shielding does not occur in the 0.1 μm naked virions studied here, is small in the 1-μm particles, and increases as particle diameters increase to 5-and 9 μm. Absorptive shielding is more important at the wavelengths of germicidal UV (260 nm used here) than it is at solar UV wavelengths (302 nm used here). Absorptive shielding is especially important in particles with diameters several times larger than the penetration depth. Refractive shielding occurs even in weakly UV-absorbing particles. UV illumination from multiple directions, widely separated, can reduce shielding ( Fig. 6 d-g) . The largest reduction in shielding occurs in particles orientationally averaged with respect to the UV illumination (equivalent to equal illumination from all directions). The extent to which these modeling results apply to actual dried droplets of respiratory fluids depends on the characteristics of the actual dried particles. Here, the optical properties of the droplets are assumed to be homogeneous (except for the virions), and all droplets and virions are assumed to be spherical. The effects of nonsphericity, inhomogeneous refractive indexes, and the effects of location of the virions are discussed in Section 4.2 . As illustrated in Fig. 1 a, and readily envisioned from ray optics [9] shielding can occur in nonspherical particles with smooth surfaces. Key points relevant to designers and users of UVGI systems, or to persons relying on inactivation by solar UVB are as follows. Virions in supermicron particles can be shielded from UV. The extent of shielding increases with particle size ( Fig. 3 ) . Shielding tends to be reduced when the UV illumination is from widely separated directions ( Fig. 6 d-g) . The reduction in shielding is greatest when the particles are illuminated equally from all directions (i.e., orientationally averaged) as in Fig. 7 . These results suggests that in designing or using UVGI systems on surfaces, shielding could be reduced by using multiple UV sources (or a mobile UV source), or by using highly reflective paints on surfaces such as walls. For UVGI systems for particles in air, these results suggest that the effectiveness of UV for inactivation of larger particles may be increased by the use of illumination times sufficient to allow particles to spin and/or tumble through multiple orientations, and/or by the use of multiple or spatially-extended UV sources. Some key questions for designs of UVGI systems for flowthrough systems for inactivating virions in particles in air are as follows. Are the particles exposed to UV illumination from enough widely separated angles to achieve approximately uniform illumination as they flow through the device? If the UV sources are pulsed, are particles exposed to enough pulses and/or are the sources large enough and/or are the reflectors or multiple sources sufficient to achieve approximately uniform illumination? Do the particles follow trajectories where they change their orientation with respect to the source(s) of UV illumination as they move through the system, and do so even if they spin and/or tumble negligibly around the particle axes? What are the sizes of the largest particles that can pass through the system (including whatever filters are in place)? These questions point to the need for an improved quantitative understanding of particle rotation (spinning and tumbling) as a function of particle size and shape for various airflows and extent of turbulence. The results point to the importance of measuring and reporting the particle size distributions in studies of transmission of disease, and in studies of inactivation of virions in dried particles of respiratory fluids. Such data could help in understanding the impact shielding might have on the survival of virions in larger dried saliva droplets, could help validate/invalidate this theoretical work, and may help in reducing the transmission of viral and other diseases. Researchers interested in the MSTM codes to calculate the results can email D.W. Mackowski. Those interested in reproducing the calculations to obtain the figures or Table 3 can email D. C. Doughty. Those interested in reproducing the calculations to obtain Tables 1 or 2 can email S. C. Hill. The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper. Sexton DJCDC Prevention Epicenters Program. Effectiveness of targeted enhanced terminal room disinfection on hospital-wide acquisition and infection with multidrug-resistant organisms and Clostridium difficile: a secondary analysis of a multicentre cluster randomized controlled trial with crossover design (BETR disinfection) Salivary uric acid is a predictive marker of body fat percentage in adolescents Aerosol emission and superemission during human speech increase with voice loudness Evaluation of UR-UVGI system for sterilization effect on microorganism contamination in negative pressure isolation ward Upper-room ultraviolet air disinfection might help to reduce COVID-19 transmission in buildings: a feasibility study The salivary flow rate and composition of whole and parotid resting and stimulated saliva in young and old healthy subjects Turbulent gas clouds and respiratory pathogen emissions potential implications for reducing transmission of COVID-19 Detection of air and surface contamination by SARS-CoV-2 in hospital rooms of infected patients Energy-density distribution inside large non-absorbing spheres by using Mie theory and geometrical optics The size and duration of air-carriage of respiratory droplets and droplet-nuclei Saliva and oral health Reaerosolization of MS 2 bacteriophage from an N 95 filtering facepiece respirator by simulated coughing The mechanics of aerosols Back to normal: an old physics route to reduce SARS-CoV-2 transmission in indoor spaces Viruses carried to soil by irrigation can be aerosolized later during windy spells Effect of a shielded continuous ultraviolet-C air disinfection device on reduction of air and surface microbial contamination in a pediatric oncology outpatient care unit Characterizations of particle size distribution of the droplets exhaled by sneeze Quantitative analysis of effects of UV exposure and spore cluster size on deposition and inhalation hazards of Bacillus spores Determination of uric acid, tyrosine, tryptophan, and protein in whole human parotid saliva by ultraviolet absorption spectrophotometry Ultraviolet irradiation doses for coronavirus inactivation-review and analysis of coronavirus photoinactivation studies Simulation of singlemolecule photocount statistics in microdroplets Fluorescence of bioaerosols: mathematical model including primary fluorescing and absorbing molecules in bacteria: errata Fluorescence of bioaerosols: mathematical model including primary fluorescing and absorbing molecules in bacteria Sizedependent fluorescence of bioaerosols: mathematical model using fluorescing and absorbing molecules in bacteria IUPAC Compendium of chemical terminology gold book-version 2.3.3. International Union of Pure and Applied Chemistry Aerosol generation by modern flush toilets Bioaerosol generation by raindrops on soil Simulation of vertical concentration gradient of influenza viruses in dust resuspended by walking Deposition method, relative humidity, and surface property effects of bacterial spore reaerosolization via pulsed air jet UV-C decontamination of aerosolized and surface-bound single spores and bioclusters UVC LED irradiation effectively inactivates aerosolized viruses, bacteria, and fungi in a chamber-type air disinfection system Ultraviolet germicidal irradiation handbook: UVGI for air and surface disinfection Reaerosolization of fluidized spores in ventilation systems Improving the effectiveness of ultraviolet germicidal irradiation through reflective wall coatings: experimental and modeling based assessments Ultraviolet germicidal irradiation inactivation of airborne fungal spores and bacteria in upper-room air and HVAC in-duct configurations Reaerosolization of Bacillus spp. in outdoor environments: a review of the experimental literature Respiratory virus shedding in exhaled breath and efficacy of face masks Can a toilet promote virus transmission? From a fluid dynamics perspective Aerodynamic analysis of SARS-CoV-2 in two Wuhan hospitals Artificial wind-gust liberation of microbial bioaerosols previously deposited on plants Exact solution for the scattering and absorption properties of sphere clusters on a plane surface Calculation of the T matrix and the scattering matrix for ensembles of spheres A multiple sphere T-matrix Fortran code for use on parallel computer clusters Direct simulation of extinction in a slab of spherical particles Mechanistic insights into the effect of humidity on airborne influenza virus survival, transmission and incidence Applications of ultraviolet germicidal irradiation disinfection in health care facilities: effective adjunct, but not stand-alone technology Influenza virus aerosols in human exhaled breath: particle size, culturability, and effect of surgical masks Size distribution and sites of origin of droplets expelled from the human respiratory tract during expiratory activities It is time to address airborne transmission of COVID-19 Airborne spread of SARS-CoV-2 and a potential role for air disinfection Effect of shadowing on survival of bacteria under conditions simulating the Martian atmosphere and UV radiation Ultraviolet-C efficacy against a norovirus surrogate and hepatitis A virus on a stainless steel surface Reaerosolization of spores from flooring surfaces to assess the risk of dissemination and transmission of infections Uric acid is a major antioxidant in human nasal airway secretions Saliva samples as a source of DNA for high throughput genotyping: an acceptable and sufficient means in improvement of risk estimation throughout mammographic diagnostics Sources of microorganisms in the built environment Walking-induced particle resuspension in indoor environments Simulated sunlight rapidly inactivates SARS-CoV-2 on surfaces Rapid hospital room decontamination using ultraviolet (UV) light with a nanostructured UV-reflective wall coating Inactivation of airborne microorganisms using novel ultraviolet radiation sources in reflective flow-through control devices Inactivation of influenza virus by solar radiation Sensitivity to ultraviolet radiation of Lassa, vaccinia, and Ebola viruses dried on surfaces Inactivation of vaccinia virus by natural sunlight and by artificial UVB radiation Estimated inactivation of coronaviruses by solar radiation with special reference to COVID-19 Persistence in darkness of virulent alphaviruses, Ebola virus, and Lassa virus deposited on solid surfaces The infectious nature of patient-generated SARS-CoV-2 aerosol The influence of simulated sunlight on the inactivation of influenza virus in aerosols Deactivation of SARS-CoV-2 with pulsed-xenon ultraviolet light: Implications for environmental COVID-19 control Hydration of proteins: excess partial volumes of water and proteins Bacillus anthracis Inactivation of viruses on surfaces by ultraviolet germicidal irradiation Aerosol and surface stability of SARS-CoV-2 as compared with SARS-CoV-1 Salivary proteins: protective and diagnostic value in cariology? Human glandular salivas: their separate collection and analysis Physico-chemical characteristics of evaporating respiratory fluid droplets Effect of ultraviolet germicidal irradiation on viral aerosols Effects of relative humidity and spraying medium on UV decontamination of filters loaded with viral aerosols Saliva or nasopharyngeal swab specimens for detection of SARS-CoV-2 The authors acknowledge partial support from the Defense Threat Reduction Agency (DTRA). Hill and Doughty acknowledge funding from the US Army DEVCOM Army Research Laboratory. The authors are thankful to one reviewer for helpful comments, and to Jay Eversole, Jana Kesavan, Frank Handler, Adam Driks (deceased), Clare Voss, Claire Bonial and Stephanie Lukin for helpful discussions. Supplementary material associated with this article can be found, in the online version, at doi: 10.1016/j.jqsrt.2020.107489 .