Future global mortality from changes in air pollution attributable to climate change

Raquel A. Silva; J. Jason West; Jean François Lamarque; Drew T. Shindell; William J. Collins; Greg Faluvegi; Gerd A. Folberth; Larry W. Horowitz; Tatsuya Nagashima; Vaishali Naik; Steven T. Rumbold; Kengo Sudo; Toshihiko Takemura; Daniel Bergmann; Philip Cameron-Smith; Ruth M. Doherty; Beatrice Josse; Ian A. MacKenzie; David S. Stevenson; Guang Zeng

doi:10.1038/nclimate3354

Future global mortality from changes in air pollution attributable to climate change

Raquel A. Silva, J. Jason West, Jean François Lamarque, Drew T. Shindell, William J. Collins, Greg Faluvegi, Gerd A. Folberth, Larry W. Horowitz, Tatsuya Nagashima, Vaishali Naik, Steven T. Rumbold, Kengo Sudo, Toshihiko Takemura, Daniel Bergmann, Philip Cameron-Smith, Ruth M. Doherty, Beatrice Josse, Ian A. MacKenzie, David S. Stevenson, Guang Zeng

Center for Oceanic and Atmospheric Research

Research output: Contribution to journal › Article › peer-review

153 Citations (Scopus)

Abstract

Ground-level ozone and fine particulate matter (PM_2.5) are associated with premature human mortality; their future concentrations depend on changes in emissions, which dominate the near-term, and on climate change. Previous global studies of the air-quality-related health effects of future climate change used single atmospheric models. However, in related studies, mortality results differ among models. Here we use an ensemble of global chemistry-climate models to show that premature mortality from changes in air pollution attributable to climate change, under the high greenhouse gas scenario RCP8.5 (ref.), is probably positive. We estimate 3,340 (-30,300 to 47,100) ozone-related deaths in 2030, relative to 2000 climate, and 43,600 (-195,000 to 237,000) in 2100 (14% of the increase in global ozone-related mortality). For PM_2.5, we estimate 55,600 (-34,300 to 164,000) deaths in 2030 and 215,000 (-76,100 to 595,000) in 2100 (countering by 16% the global decrease in PM_2.5-related mortality). Premature mortality attributable to climate change is estimated to be positive in all regions except Africa, and is greatest in India and East Asia. Most individual models yield increased mortality from climate change, but some yield decreases, suggesting caution in interpreting results from a single model. Climate change mitigation is likely to reduce air-pollution-related mortality.

Original language	English
Pages (from-to)	647-651
Number of pages	5
Journal	Nature Climate Change
Volume	7
Issue number	9
DOIs	https://doi.org/10.1038/nclimate3354
Publication status	Published - Sept 1 2017

All Science Journal Classification (ASJC) codes

Environmental Science (miscellaneous)
Social Sciences (miscellaneous)

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Silva, R. A., West, J. J., Lamarque, J. F., Shindell, D. T., Collins, W. J., Faluvegi, G., Folberth, G. A., Horowitz, L. W., Nagashima, T., Naik, V., Rumbold, S. T., Sudo, K., Takemura, T., Bergmann, D., Cameron-Smith, P., Doherty, R. M., Josse, B., MacKenzie, I. A., Stevenson, D. S., & Zeng, G. (2017). Future global mortality from changes in air pollution attributable to climate change. Nature Climate Change, 7(9), 647-651. https://doi.org/10.1038/nclimate3354

Silva, RA, West, JJ, Lamarque, JF, Shindell, DT, Collins, WJ, Faluvegi, G, Folberth, GA, Horowitz, LW, Nagashima, T, Naik, V, Rumbold, ST, Sudo, K, Takemura, T, Bergmann, D, Cameron-Smith, P, Doherty, RM, Josse, B, MacKenzie, IA, Stevenson, DS & Zeng, G 2017, 'Future global mortality from changes in air pollution attributable to climate change', Nature Climate Change, vol. 7, no. 9, pp. 647-651. https://doi.org/10.1038/nclimate3354

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title = "Future global mortality from changes in air pollution attributable to climate change",

abstract = "Ground-level ozone and fine particulate matter (PM2.5) are associated with premature human mortality; their future concentrations depend on changes in emissions, which dominate the near-term, and on climate change. Previous global studies of the air-quality-related health effects of future climate change used single atmospheric models. However, in related studies, mortality results differ among models. Here we use an ensemble of global chemistry-climate models to show that premature mortality from changes in air pollution attributable to climate change, under the high greenhouse gas scenario RCP8.5 (ref.), is probably positive. We estimate 3,340 (-30,300 to 47,100) ozone-related deaths in 2030, relative to 2000 climate, and 43,600 (-195,000 to 237,000) in 2100 (14% of the increase in global ozone-related mortality). For PM2.5, we estimate 55,600 (-34,300 to 164,000) deaths in 2030 and 215,000 (-76,100 to 595,000) in 2100 (countering by 16% the global decrease in PM2.5-related mortality). Premature mortality attributable to climate change is estimated to be positive in all regions except Africa, and is greatest in India and East Asia. Most individual models yield increased mortality from climate change, but some yield decreases, suggesting caution in interpreting results from a single model. Climate change mitigation is likely to reduce air-pollution-related mortality.",

author = "Silva, {Raquel A.} and West, {J. Jason} and Lamarque, {Jean Fran{\c c}ois} and Shindell, {Drew T.} and Collins, {William J.} and Greg Faluvegi and Folberth, {Gerd A.} and Horowitz, {Larry W.} and Tatsuya Nagashima and Vaishali Naik and Rumbold, {Steven T.} and Kengo Sudo and Toshihiko Takemura and Daniel Bergmann and Philip Cameron-Smith and Doherty, {Ruth M.} and Beatrice Josse and MacKenzie, {Ian A.} and Stevenson, {David S.} and Guang Zeng",

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AU - Silva, Raquel A.

AU - West, J. Jason

AU - Lamarque, Jean François

AU - Shindell, Drew T.

AU - Collins, William J.

AU - Faluvegi, Greg

AU - Folberth, Gerd A.

AU - Horowitz, Larry W.

AU - Nagashima, Tatsuya

AU - Naik, Vaishali

AU - Rumbold, Steven T.

AU - Sudo, Kengo

AU - Takemura, Toshihiko

AU - Bergmann, Daniel

AU - Cameron-Smith, Philip

AU - Doherty, Ruth M.

AU - Josse, Beatrice

AU - MacKenzie, Ian A.

AU - Stevenson, David S.

AU - Zeng, Guang

PY - 2017/9/1

Y1 - 2017/9/1

N2 - Ground-level ozone and fine particulate matter (PM2.5) are associated with premature human mortality; their future concentrations depend on changes in emissions, which dominate the near-term, and on climate change. Previous global studies of the air-quality-related health effects of future climate change used single atmospheric models. However, in related studies, mortality results differ among models. Here we use an ensemble of global chemistry-climate models to show that premature mortality from changes in air pollution attributable to climate change, under the high greenhouse gas scenario RCP8.5 (ref.), is probably positive. We estimate 3,340 (-30,300 to 47,100) ozone-related deaths in 2030, relative to 2000 climate, and 43,600 (-195,000 to 237,000) in 2100 (14% of the increase in global ozone-related mortality). For PM2.5, we estimate 55,600 (-34,300 to 164,000) deaths in 2030 and 215,000 (-76,100 to 595,000) in 2100 (countering by 16% the global decrease in PM2.5-related mortality). Premature mortality attributable to climate change is estimated to be positive in all regions except Africa, and is greatest in India and East Asia. Most individual models yield increased mortality from climate change, but some yield decreases, suggesting caution in interpreting results from a single model. Climate change mitigation is likely to reduce air-pollution-related mortality.

AB - Ground-level ozone and fine particulate matter (PM2.5) are associated with premature human mortality; their future concentrations depend on changes in emissions, which dominate the near-term, and on climate change. Previous global studies of the air-quality-related health effects of future climate change used single atmospheric models. However, in related studies, mortality results differ among models. Here we use an ensemble of global chemistry-climate models to show that premature mortality from changes in air pollution attributable to climate change, under the high greenhouse gas scenario RCP8.5 (ref.), is probably positive. We estimate 3,340 (-30,300 to 47,100) ozone-related deaths in 2030, relative to 2000 climate, and 43,600 (-195,000 to 237,000) in 2100 (14% of the increase in global ozone-related mortality). For PM2.5, we estimate 55,600 (-34,300 to 164,000) deaths in 2030 and 215,000 (-76,100 to 595,000) in 2100 (countering by 16% the global decrease in PM2.5-related mortality). Premature mortality attributable to climate change is estimated to be positive in all regions except Africa, and is greatest in India and East Asia. Most individual models yield increased mortality from climate change, but some yield decreases, suggesting caution in interpreting results from a single model. Climate change mitigation is likely to reduce air-pollution-related mortality.

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JO - Nature Climate Change

JF - Nature Climate Change

IS - 9

ER -

Future global mortality from changes in air pollution attributable to climate change

Abstract

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