Your search keyword '"Akoshile, Clement"' showing total 18 results

1. Regional estimation of geothermal resources of the entire Benue Trough, Nigeria using high-resolution aeromagnetic data

Author

Dopamu, Kehinde Oladele, Akoshile, Clement O., and Nwankwo, Levi Ikechukwu

Published

2021

2. Large global variations in measured airborne metal concentrations driven by anthropogenic sources

Author

McNeill, Jacob, Snider, Graydon, Weagle, Crystal L., Walsh, Brenna, Bissonnette, Paul, Stone, Emily, Abboud, Ihab, Akoshile, Clement, Anh, Nguyen Xuan, Balasubramanian, Rajasekhar, Brook, Jeffrey R., Coburn, Craig, Cohen, Aaron, Dong, Jinlu, Gagnon, Graham, Garland, Rebecca M., He, Kebin, Holben, Brent N., Kahn, Ralph, Kim, Jong Sung, Lagrosas, Nofel, Lestari, Puji, Liu, Yang, Jeba, Farah, Joy, Khaled Shaifullah, Martins, J. Vanderlei, Misra, Amit, Norford, Leslie K., Quel, Eduardo J., Salam, Abdus, Schichtel, Bret, Tripathi, S. N., Wang, Chien, Zhang, Qiang, Brauer, Michael, Gibson, Mark D., Rudich, Yinon, and Martin, Randall V.

Published

2020

3. Experimental Investigation of Heat Losses from a Heat Pipe Based Parabolic Trough Collector used for Direct Steam Generation

Author

Akoshile Clement Olufemi and Abiem Louis Tersoo

Subjects

Heat pipe, Materials science, Parabolic trough, Heat losses, Thermosiphon, Mechanics, Steam generation

Abstract

The performance of a thermosiphon based parabolic trough collector (PTC) used for direct steam generation depends largely on the heat losses of the solar thermal system. This paper presents an experimental investigation of the heat losses in a thermosiphon based solar thermal system that used a linear receiver with a PTC for the generation of low temperature steam. A locally constructed PTC was used to concentrate sun rays to a linear copper pipe enclosed in an evacuated glass tube and held at the focal line of the PTC to heat water and generate steam. Circulation of the water in the closed-loop solar thermal system was through natural convection. A solar meter was used to measure the incident radiation flux at the experimental site and PT100 temperature sensors were installed at different points of the system to measure the temperature distribution within the system. The thermal efficiency and overall heat losses of the system were investigated by fitting the experimental data to standard equations. The results showed that the instantaneous thermal efficiency of the system was 46.48%, 43.1% and 45.32% respectively for three days examined. The overall heat losses in the system were 1211.95, 974.32 and 911.26 kwh per day respectively for the three days investigated. Heat losses from the tank accounted for over 83% of the losses for all the days examined. The evacuated glass tube reduced heat losses from the receiver to very low values of 2.31, 1.63 and 1.43 KWh per day respectively for the three days tested. The use of a better insulating material on the tank was recommended to reduce convective and conductive heat losses, thereby enhancing the performance of the system.

Published

2021

4. Variation in Global Chemical Composition of PM2.5: Emerging Results from SPARTAN

Author

Snider, Graydon, Weagle, Crystal L, Murdymootoo, Kalaivani K, Ring, Amanda, Ritchie, Yvonne, Stone, Emily, Walsh, Ainsley, Akoshile, Clement, Anh, Nguyen Xuan, Balasubramanian, Rajasekhar, Brook, Jeff, Qonitan, Fatimah D, Dong, Jinlu, Griffith, Derek, He, Kebin, Holben, Brent N, Kahn, Ralph, Lagrosas, Nofel, Lestari, Puji, Ma, Zongwei, Misra, Amit, Norford, Leslie K, Quel, Eduardo J, Salam, Abdus, Schichtel, Bret, Segev, Lior, Tripathi, Sachchida, Wang, Chien, Yu, Chao, Zhang, Qiang, Zhang, Yuxuan, Brauer, Michael, Cohen, Aaron, Gibson, Mark D, Liu, Yang, Martins, J. Vanderlei, Rudich, Yinon, and Martin, Randall V

Subjects

Environment Pollution

Abstract

The Surface PARTiculate mAtter Network (SPARTAN) is a long-term project that includes characterization of chemical and physical attributes of aerosols from filter samples collected worldwide. This paper discusses the ongoing efforts of SPARTAN to define and quantify major ions and trace metals found in fine particulate matter (PM (sub 2.5). Our methods infer the spatial and temporal variability of PM (sub 2.5) in a cost-effective manner. Gravimetrically weighed filters represent multi-day averages of PM (sub 2.5), with a collocated nephelometer sampling air continuously. SPARTAN instruments are paired with AErosol RObotic NETwork (AERONET) sun photometers to better understand the relationship between ground-level PM (sub 2.5) and columnar aerosol optical depth (AOD). We have examined the chemical composition of PM (sub 2.5) at 12 globally dispersed, densely populated urban locations and a site at Mammoth Cave (US) National Park used as a background comparison. So far, each SPARTAN location has been active between the years 2013 and 2016 over periods of 2-26 months, with an average period of 12 months per site. These sites have collectively gathered over 10 years of quality aerosol data. The major PM (sub 2.5) constituents across all sites (relative contribution plus or minus Standard Deviation) are ammoniated sulfate (20 percent plus or minus 11 percent), crustal material (13.4 percent plus or minus 9.9 percent), equivalent black carbon (11.9 percent plus or minus 8.4 percent), ammonium nitrate (4.7 percent plus or minus 3.0 percent), sea salt (2.3 percent plus or minus 1.6 percent), trace element oxides (1.0 percent plus or minus 1.1 percent), water (7.2 percent plus or minus 3.3 percent) at 35 percent relative humidity, and residual matter (40 percent plus or minus 24 percent). Analysis of filter samples reveals that several PM (sub 2.5) chemical components varied by more than an order of magnitude between sites. Ammoniated sulfate ranges from 1.1 microns per cubic meter (Buenos Aires, Argentina) to 17 microns per cubic meter (Kanpur, India in the dry season). Ammonium nitrate ranged from 0.2 microns per cubic meter (Mammoth Cave, in summer) to 6.8 microns per cubic meter (Kanpur, dry season). Equivalent black carbon ranged from 0.7 microns per cubic meter (Mammoth Cave) to over 8 microns per cubic meter (Dhaka, Bangladesh and Kanpur, India). Comparison of SPARTAN vs. coincident measurements from the Interagency Monitoring of Protected Visual Environments (IMPROVE) network at Mammoth Cave yielded a high degree of consistency for daily PM (sub 2.5) (r squared equals 0.76, slope equals 1.12), daily sulfate (r squared equals 0.86, slope equals 1.03), and mean fractions of all major PM (sub 2.5) components (within 6 percent). Major ions generally agree well with previous studies at the same urban locations (e.g. sulfate fractions agree within 4 percent for 8 out of 11 collocation comparisons). Enhanced anthropogenic dust fractions in large urban areas (e.g. Singapore, Kanpur, Hanoi, and Dhaka) are apparent from high Zn to Al ratios. The expected water contribution to aerosols is calculated via the hygroscopicity parameter kappa (sub v (volume)) for each filter. Mean aggregate values ranged from 0.15 (Ilorin) to 0.28 (Rehovot). The all-site parameter mean is 0.20 plus or minus 0.04. Chemical composition and water retention in each filter measurement allows inference of hourly PM (sub 2.5) at 35 percent relative humidity by merging with nephelometer measurements. These hourly PM (sub 2.5) estimates compare favourably with a beta attenuation monitor (MetOne) at the nearby US embassy in Beijing, with a coefficient of variation r squared equals 0.67 (number equals 3167), compared to r squared equals 0.62 when v (volume) was not considered. SPARTAN continues to provide an open-access database of PM (sub 2.5) compositional filter information and hourly mass collected from a global federation of instruments.

Published

2016

5. Development and Implementation of a Low-cost Automatic Dual-axis Solar Tracker through Hardware/Software Embedded Program Control

Author

Abiem, Louis Tersoo, primary, Akoshile, Clement Olufemi, primary, and Ajibola, Taiye Benjamin, primary

Published

2021

6. Experimental Investigation of Heat Losses from a Heat Pipe Based Parabolic Trough Collector used for Direct Steam Generation

Author

Tersoo, Abiem Louis, primary and Olufemi, Akoshile Clement, primary

Published

2021

7. Review of Evidence of Aerosol Transmission of SARS-CoV-2 Particles

Author

Aladodo, Shehu Sharafadeen, primary, Akoshile, Clement Olufemi, additional, and Otu, J. O., additional

Published

2021

8. Radiological Hazards Associated with 238U, 232Th, and 40K in some selected Packaged Drinking Water in Ilorin and Ogbomoso, Nigeria.

Author

Benjamine, Ajibola Taiye, Michael, Orosun Muyiwa, Emmanuel, Ehinlafa Olusegun, Anike, Sharafudeen Fatimah, Naheem, Salawu Banji, Olatunji, Simon, and O., Akoshile Clement

Subjects

RADIOACTIVITY, DRINKING water, SPECTROMETRY, GAMMA rays, RADIATION

Abstract

In order to ensure radiation monitoring and protection, investigation and assessment of radiological risks that may be associated with the consumption of packaged table waters commonly consumed in Ogbomoso and Ilorin metropolis, Nigeria, was carried out. The measurements were carried out using a '3 x 3' inch lead-shielded NaI (Tl) detector coupled through coaxial cable to a multichannel analyser. The measured activity concentrations of the natural radionuclides in the packaged drinking water sample are mostly within the recommended limits. The estimated mean Annual Effective Dose was found to be within the acceptable limits of 1 mSv/y for the general populace except for the infants which is slightly higher for some of the samples. The estimated Excess Lifetime Cancer Risk were found to be lower than the world average value of 0.2 x 10-3 in only two of the selected packaged drinking water. This implies the possibility of developing cancer over a lifetime considering seventy years as the average life span is considerably high. [ABSTRACT FROM AUTHOR]

Published

2022

9. Thermal Efficiency Evaluation of a Solar Thermal Steam Generating System Using Thermosiphon Technique with Parabolic Trough Collector

Author

Akoshile Clement Olufemi and Abiem Louis Tersoo

Subjects

Thermal efficiency, Materials science, Natural circulation, Thermal, Parabolic trough, Mechanics, Thermosiphon, Heat sink, Pressure sensor, Intensity (heat transfer)

Abstract

Parabolic trough solar collectors are the most widely used concentrators for solar thermal applications in the world. This is because very high temperatures of 150°C to 350°C can be attained with its use without any noticeable degradation in the performance of the collector. In this work, a parabolic trough collector (PTC) was designed using simple parabolic equations and constructed with locally sourced materials. The developed PTC was used to converge direct solar radiation to a heat receiver (a copper pipe enclosed in an evacuated glass tube) placed at the focal line of the trough to heat up the water in the pipe to steam. Natural circulation (thermosiphon) was employed to drive the water from the heat source to the heat sink (tank) with the difference in density as the driving force of the system. Temperature sensors were installed at different points of the solar thermal system to experimentally investigate temperature distribution within the system, hence thermal performance. A pressure sensor was also installed in the tank to measure the pressure within the system. The results obtained shows that the solar thermal system generated low-mid temperature steam of up to 105°C at a pressure of approximately 120 kPa on a day when the global solar radiation intensity attained a value of 1109.5 W/m2. A thermosiphon mass flow rate of up to 0.042 kg/s was also recorded through a constant orifice of 12 mm diameter. The instantaneous efficiency of the receiver reached 46.48%.

Published

2020

10. Comparative Accuracy Assessment of Combined MODIS and NAAPS Aerosol Optical Depth with AERONET Data over North Africa

Author

Akoshile, Clement O., primary, Shehu-Aladodo, Sarafadeen, additional, Sani, Muawiya, additional, Otu, Jibril O., additional, and Ajibola, Benjamin T., additional

Published

2019

11. Global Sources of Fine Particulate Matter: Interpretation of PM2.5 Chemical Composition Observed by SPARTAN using a Global Chemical Transport Model

Author

Weagle, Crystal L., primary, Snider, Graydon, additional, Li, Chi, additional, van Donkelaar, Aaron, additional, Philip, Sajeev, additional, Bissonnette, Paul, additional, Burke, Jaqueline, additional, Jackson, John, additional, Latimer, Robyn, additional, Stone, Emily, additional, Abboud, Ihab, additional, Akoshile, Clement, additional, Anh, Nguyen Xuan, additional, Brook, Jeffrey Robert, additional, Cohen, Aaron, additional, Dong, Jinlu, additional, Gibson, Mark D., additional, Griffith, Derek, additional, He, Kebin B., additional, Holben, Brent N., additional, Kahn, Ralph, additional, Keller, Christoph A., additional, Kim, Jong Sung, additional, Lagrosas, Nofel, additional, Lestari, Puji, additional, Khian, Yeo Lik, additional, Liu, Yang, additional, Marais, Eloise A., additional, Martins, J. Vanderlei, additional, Misra, Amit, additional, Muliane, Ulfi, additional, Pratiwi, Rizki, additional, Quel, Eduardo J., additional, Salam, Abdus, additional, Segev, Lior, additional, Tripathi, Sachchida N., additional, Wang, Chien, additional, Zhang, Qiang, additional, Brauer, Michael, additional, Rudich, Yinon, additional, and Martin, Randall V., additional

Published

2018

12. Global Sources of Fine Particulate Matter: Interpretation of PM2.5Chemical Composition Observed by SPARTAN using a Global Chemical Transport Model

Author

Weagle, Crystal L., Snider, Graydon, Li, Chi, van Donkelaar, Aaron, Philip, Sajeev, Bissonnette, Paul, Burke, Jaqueline, Jackson, John, Latimer, Robyn, Stone, Emily, Abboud, Ihab, Akoshile, Clement, Anh, Nguyen Xuan, Brook, Jeffrey Robert, Cohen, Aaron, Dong, Jinlu, Gibson, Mark D., Griffith, Derek, He, Kebin B., Holben, Brent N., Kahn, Ralph, Keller, Christoph A., Kim, Jong Sung, Lagrosas, Nofel, Lestari, Puji, Khian, Yeo Lik, Liu, Yang, Marais, Eloise A., Martins, J. Vanderlei, Misra, Amit, Muliane, Ulfi, Pratiwi, Rizki, Quel, Eduardo J., Salam, Abdus, Segev, Lior, Tripathi, Sachchida N., Wang, Chien, Zhang, Qiang, Brauer, Michael, Rudich, Yinon, and Martin, Randall V.

Abstract

Exposure to ambient fine particulate matter (PM2.5) is a leading risk factor for the global burden of disease. However, uncertainty remains about PM2.5sources. We use a global chemical transport model (GEOS-Chem) simulation for 2014, constrained by satellite-based estimates of PM2.5to interpret globally dispersed PM2.5mass and composition measurements from the ground-based surface particulate matter network (SPARTAN). Measured site mean PM2.5composition varies substantially for secondary inorganic aerosols (2.4–19.7 μg/m3), mineral dust (1.9–14.7 μg/m3), residual/organic matter (2.1–40.2 μg/m3), and black carbon (1.0–7.3 μg/m3). Interpretation of these measurements with the GEOS-Chem model yields insight into sources affecting each site. Globally, combustion sectors such as residential energy use (7.9 μg/m3), industry (6.5 μg/m3), and power generation (5.6 μg/m3) are leading sources of outdoor global population-weighted PM2.5concentrations. Global population-weighted organic mass is driven by the residential energy sector (64%) whereas population-weighted secondary inorganic concentrations arise primarily from industry (33%) and power generation (32%). Simulation-measurement biases for ammonium nitrate and dust identify uncertainty in agricultural and crustal sources. Interpretation of initial PM2.5mass and composition measurements from SPARTAN with the GEOS-Chem model constrained by satellite-based PM2.5provides insight into sources and processes that influence the global spatial variation in PM2.5composition.

Published

2024

13. SPARTAN: An Emerging Global Aerosol Network

Author

Graydon A Snider, Weagle, Crystal, Martin, Randall, Donkelaar, Aaron Van, Akoshile, Clement, Artaxo, Paulo, Brook, Jeff, Holben, Brent, Kahn, Ralph, Nofel Lagrosas, Puji Lestari, Vanderlei J. Martins, Quel, Eduardo J., Rudich, Yinon, Abdus Salam, S.N. Tripathi, Qiang, Zhang, Brauer, Michael, Cohen, Aaron, Gibson, Mark D., and Liu, Yang

Published

2014

14. Variation in Global Chemical Composition of PM<sub>2.5</sub>: Emerging Results from SPARTAN

Author

Snider, Graydon, primary, Weagle, Crystal L., additional, Murdymootoo, Kalaivani K., additional, Ring, Amanda, additional, Ritchie, Yvonne, additional, Walsh, Ainsley, additional, Akoshile, Clement, additional, Anh, Nguyen Xuan, additional, Brook, Jeff, additional, Qonitan, Fatimah D., additional, Dong, Jinlu, additional, Griffith, Derek, additional, He, Kebin, additional, Holben, Brent N., additional, Kahn, Ralph, additional, Lagrosas, Nofel, additional, Lestari, Puji, additional, Ma, Zongwei, additional, Misra, Amit, additional, Quel, Eduardo J., additional, Salam, Abdus, additional, Schichtel, Bret, additional, Segev, Lior, additional, Tripathi, S. N., additional, Wang, Chien, additional, Yu, Chao, additional, Zhang, Qiang, additional, Zhang, Yuxuan, additional, Brauer, Michael, additional, Cohen, Aaron, additional, Gibson, Mark D., additional, Liu, Yang, additional, Martins, J. Vanderlei, additional, Rudich, Yinon, additional, and Martin, Randall V., additional

Published

2016

15. Global Sources of Fine Particulate Matter: Interpretation of PM2.5 Chemical Composition Observed by SPARTAN using a Global Chemical Transport Model.

Author

Weagle, Crystal L., Snider, Graydon, Li, Chi, van Donkelaar, Aaron, Philip, Sajeev, Bissonnette, Paul, Burke, Jaqueline, Jackson, John, Latimer, Robyn, Stone, Emily, Abboud, Ihab, Akoshile, Clement, Anh, Nguyen Xuan, Brook, Jeffrey Robert, Cohen, Aaron, Dong, Jinlu, Gibson, Mark D., Griffith, Derek, He, Kebin B., and Holben, Brent N.

Published

2018

16. Variation in global chemical composition of PM2:5: emerging results from SPARTAN.

Author

Snider, Graydon, Weagle, Crystal L., Murdymootoo, Kalaivani K., Ring, Amanda, Ritchie, Yvonne, Stone, Emily, Walsh, Ainsley, Akoshile, Clement, Nguyen Xuan Anh, Balasubramanian, Rajasekhar, Brook, Jeff, Qonitan, Fatimah D., Jinlu Dong, Griffith, Derek, Kebin He, Holben, Brent N., Kahn, Ralph, Lagrosas, Nofel, Lestari, Puji, and Zongwei Ma

Subjects

ATMOSPHERIC composition, CLIMATE change, PARTICULATE matter, OPTICAL properties of atmospheric aerosols

Abstract

The Surface PARTiculate mAtter Network (SPARTAN) is a long-term project that includes characterization of chemical and physical attributes of aerosols from filter samples collected worldwide. This paper discusses the ongoing efforts of SPARTAN to define and quantify major ions and trace metals found in fine particulate matter (PM2:5). Our methods infer the spatial and temporal variability of PM2:5 in a cost-effective manner. Gravimetrically weighed filters represent multi-day averages of PM2:5, with a collocated nephelometer sampling air continuously. SPARTAN instruments are paired with AErosol RObotic NETwork (AERONET) sun photometers to better understand the relationship between ground-level PM2:5 and columnar aerosol optical depth (AOD). We have examined the chemical composition of PM2:5 at 12 globally dispersed, densely populated urban locations and a site at Mammoth Cave (US) National Park used as a background comparison. So far, each SPARTAN location has been active between the years 2013 and 2016 over periods of 2-26 months, with an average period of 12 months per site. These sites have collectively gathered over 10 years of quality aerosol data. The major PM2:5 constituents across all sites (relative contribution±SD) are ammoniated sulfate (20%±11%), crustal material (13.4% ±9.9%), equivalent black carbon (11.9%±8.4%), ammonium nitrate (4.7%±3.0%), sea salt (2.3%± 1.6%), trace element oxides (1.0%±1.1%), water (7.2% ±3.3%) at 35% RH, and residual matter (40%±24%). Analysis of filter samples reveals that several PM2:5 chemical components varied by more than an order of magnitude between sites. Ammoniated sulfate ranges from 1.1 µgm-3 (Buenos Aires, Argentina) to 17 µgm-3 (Kanpur, India in the dry season). Ammonium nitrate ranged from 0.2 µgm-3 (Mammoth Cave, in summer) to 6.8 µgm-3 (Kanpur, dry season). Equivalent black carbon ranged from 0.7 µgm-3 (Mammoth Cave) to over 8 µgm-3 (Dhaka, Bangladesh and Kanpur, India). Comparison of SPARTAN vs. coincident measurements from the Interagency Monitoring of Protected Visual Environments (IMPROVE) network at Mammoth Cave yielded a high degree of consistency for daily PM2:5 (r² = 0.76, slopeD1.12), daily sulfate (r² = 0.86, slopeD1.03), and mean fractions of all major PM2:5 components (within 6%). Major ions generally agree well with previous studies at the same urban locations (e.g. sulfate fractions agree within 4% for 8 out of 11 collocation comparisons). Enhanced anthropogenic dust fractions in large urban areas (e.g. Singapore, Kanpur, Hanoi, and Dhaka) are apparent from high Zn : Al ratios. The expected water contribution to aerosols is calculated via the hygroscopicity parameter Kv for each filter. Mean aggregate values ranged from 0.15 (Ilorin) to 0.28 (Rehovot). The all-site parameter mean is 0.20±0.04. Chemical composition and water retention in each filter measurement allows inference of hourly PM2:5 at 35% relative humidity by merging with nephelometer measurements. These hourly PM2:5 estimates compare favourably with a beta attenuation monitor (MetOne) at the nearby US embassy in Beijing, with a coefficient of variation r² = 0.67 (n = 3167), compared to r² = 0.62 when Kv was not considered. SPARTAN continues to provide an open-access database of PM2:5 compositional filter information and hourly mass collected from a global federation of instruments. [ABSTRACT FROM AUTHOR]

Published

2016

17. Elemental Characterization of Ambient Particulate Matter for a Globally Distributed Monitoring Network: Methodology and Implications.

Author

Liu X, Turner JR, Oxford CR, McNeill J, Walsh B, Le Roy E, Weagle CL, Stone E, Zhu H, Liu W, Wei Z, Hyslop NP, Giacomo J, Dillner AM, Salam A, Hossen AA, Islam Z, Abboud I, Akoshile C, Amador-Muñoz O, Anh NX, Asfaw A, Balasubramanian R, Chang RY, Coburn C, Dey S, Diner DJ, Dong J, Farrah T, Gahungu P, Garland RM, Grutter de la Mora M, Hasheminassab S, John J, Kim J, Kim JS, Langerman K, Lee PC, Lestari P, Liu Y, Mamo T, Martins M, Mayol-Bracero OL, Naidoo M, Park SS, Schechner Y, Schofield R, Tripathi SN, Windwer E, Wu MT, Zhang Q, Brauer M, Rudich Y, and Martin RV

Abstract

Global ground-level measurements of elements in ambient particulate matter (PM) can provide valuable information to understand the distribution of dust and trace elements, assess health impacts, and investigate emission sources. We use X-ray fluorescence spectroscopy to characterize the elemental composition of PM samples collected from 27 globally distributed sites in the Surface PARTiculate mAtter Network (SPARTAN) over 2019-2023. Consistent protocols are applied to collect all samples and analyze them at one central laboratory, which facilitates comparison across different sites. Multiple quality assurance measures are performed, including applying reference materials that resemble typical PM samples, acceptance testing, and routine quality control. Method detection limits and uncertainties are estimated. Concentrations of dust and trace element oxides (TEO) are determined from the elemental dataset. In addition to sites in arid regions, a moderately high mean dust concentration (6 μg/m 3 ) in PM 2.5 is also found in Dhaka (Bangladesh) along with a high average TEO level (6 μg/m 3 ). High carcinogenic risk (>1 cancer case per 100000 adults) from airborne arsenic is observed in Dhaka (Bangladesh), Kanpur (India), and Hanoi (Vietnam). Industries of informal lead-acid battery and e-waste recycling as well as coal-fired brick kilns likely contribute to the elevated trace element concentrations found in Dhaka., Competing Interests: The authors declare no competing financial interest., (© 2024 The Authors. Published by American Chemical Society.)

Published

2024

18. Global Sources of Fine Particulate Matter: Interpretation of PM 2.5 Chemical Composition Observed by SPARTAN using a Global Chemical Transport Model.

Author

Weagle CL, Snider G, Li C, van Donkelaar A, Philip S, Bissonnette P, Burke J, Jackson J, Latimer R, Stone E, Abboud I, Akoshile C, Anh NX, Brook JR, Cohen A, Dong J, Gibson MD, Griffith D, He KB, Holben BN, Kahn R, Keller CA, Kim JS, Lagrosas N, Lestari P, Khian YL, Liu Y, Marais EA, Martins JV, Misra A, Muliane U, Pratiwi R, Quel EJ, Salam A, Segev L, Tripathi SN, Wang C, Zhang Q, Brauer M, Rudich Y, and Martin RV

Subjects

Aerosols, Dust, Environmental Monitoring, Air Pollutants, Particulate Matter

Abstract

Exposure to ambient fine particulate matter (PM 2.5 ) is a leading risk factor for the global burden of disease. However, uncertainty remains about PM 2.5 sources. We use a global chemical transport model (GEOS-Chem) simulation for 2014, constrained by satellite-based estimates of PM 2.5 to interpret globally dispersed PM 2.5 mass and composition measurements from the ground-based surface particulate matter network (SPARTAN). Measured site mean PM 2.5 composition varies substantially for secondary inorganic aerosols (2.4-19.7 μg/m 3 ), mineral dust (1.9-14.7 μg/m 3 ), residual/organic matter (2.1-40.2 μg/m 3 ), and black carbon (1.0-7.3 μg/m 3 ). Interpretation of these measurements with the GEOS-Chem model yields insight into sources affecting each site. Globally, combustion sectors such as residential energy use (7.9 μg/m 3 ), industry (6.5 μg/m 3 ), and power generation (5.6 μg/m 3 ) are leading sources of outdoor global population-weighted PM 2.5 concentrations. Global population-weighted organic mass is driven by the residential energy sector (64%) whereas population-weighted secondary inorganic concentrations arise primarily from industry (33%) and power generation (32%). Simulation-measurement biases for ammonium nitrate and dust identify uncertainty in agricultural and crustal sources. Interpretation of initial PM 2.5 mass and composition measurements from SPARTAN with the GEOS-Chem model constrained by satellite-based PM 2.5 provides insight into sources and processes that influence the global spatial variation in PM 2.5 composition.

Published

2018