Neal L Fann1, Christopher G Nolte2, Marcus C Sarofim3, Jeremy Martinich3, Nicholas J Nassikas4. 1. Office of Air Quality Planning and Standards, Office of Air and Radiation, US Environmental Protection Agency, Research Triangle Park, North Carolina. 2. Center for Environmental Measurement and Modeling, Office of Research and Development, US Environmental Protection Agency, Research Triangle Park, North Carolina. 3. Office of Atmospheric Programs, Office of Air and Radiation, US Environmental Protection Agency, Washington District of Columbia. 4. Department of Pulmonary, Critical Care, and Sleep Medicine, Alpert School of Medicine, Brown University, Providence, Rhode Island.
Abstract
Importance: Future changes in climate are likely to adversely affect human health by affecting concentrations of particulate matter sized less than 2.5 μm (PM2.5) and ozone (O3) in many areas. However, the degree to which these outcomes may be mitigated by reducing air pollutant emissions is not well understood. Objective: To model the associations between future changes in climate, air quality, and human health for 2 climate models and under 2 air pollutant emission scenarios. Design, Setting, and Participants: This modeling study simulated meteorological conditions over the coterminous continental US during a 1995 to 2005 baseline and over the 21st century (2025-2100) by dynamically downscaling representations of a high warming scenario from the Community Earth System Model (CESM) and the Coupled Model version 3 (CM3) global climate models. Using a chemical transport model, PM2.5 and O3 concentrations were simulated under a 2011 air pollutant emission data set and a 2040 projection. The changes in PM2.5 and O3-attributable deaths associated with climate change among the US census-projected population were estimated for 2030, 2050, 2075, and 2095 for each of 2 emission inventories and climate models. Data were analyzed from June 2018 to June 2020. Main Outcomes and Measures: The main outcomes were simulated change in summer season means of the maximum daily 8-hour mean O3, annual mean PM2.5, population-weighted exposure, and the number of avoided or incurred deaths associated with these pollutants. Results are reported for 2030, 2050, 2075, and 2095, compared with 2000, for 2 climate models and 2 air pollutant emissions data sets. Results: The projected increased maximum daily temperatures through 2095 were up to 7.6 °C for the CESM model and 11.8 °C for the CM3 model. Under each climate model scenario by 2095, compared with 2000, an estimated additional 21 000 (95% CI, 14 000-28 000) PM2.5-attributable deaths and 4100 (95% CI, 2200-6000) O3-attributable deaths were projected to occur. These projections decreased to an estimated 15 000 (95% CI, 10 000-20 000) PM2.5-attributable deaths and 640 (95% CI, 340-940) O3-attributable deaths when simulated using a future emission inventory that accounted for reduced anthropogenic emissions. Conclusions and Relevance: These findings suggest that reducing future air pollutant emissions could also reduce the climate-driven increase in deaths associated with air pollution by hundreds to thousands.
Importance: Future changes in climate are likely to adversely affect human health by affecting concentrations of particulate matter sized less than 2.5 μm (PM2.5) and ozone (O3) in many areas. However, the degree to which these outcomes may be mitigated by reducing air pollutant emissions is not well understood. Objective: To model the associations between future changes in climate, air quality, and human health for 2 climate models and under 2 air pollutant emission scenarios. Design, Setting, and Participants: This modeling study simulated meteorological conditions over the coterminous continental US during a 1995 to 2005 baseline and over the 21st century (2025-2100) by dynamically downscaling representations of a high warming scenario from the Community Earth System Model (CESM) and the Coupled Model version 3 (CM3) global climate models. Using a chemical transport model, PM2.5 and O3 concentrations were simulated under a 2011 air pollutant emission data set and a 2040 projection. The changes in PM2.5 and O3-attributable deaths associated with climate change among the US census-projected population were estimated for 2030, 2050, 2075, and 2095 for each of 2 emission inventories and climate models. Data were analyzed from June 2018 to June 2020. Main Outcomes and Measures: The main outcomes were simulated change in summer season means of the maximum daily 8-hour mean O3, annual mean PM2.5, population-weighted exposure, and the number of avoided or incurred deaths associated with these pollutants. Results are reported for 2030, 2050, 2075, and 2095, compared with 2000, for 2 climate models and 2 air pollutant emissions data sets. Results: The projected increased maximum daily temperatures through 2095 were up to 7.6 °C for the CESM model and 11.8 °C for the CM3 model. Under each climate model scenario by 2095, compared with 2000, an estimated additional 21 000 (95% CI, 14 000-28 000) PM2.5-attributable deaths and 4100 (95% CI, 2200-6000) O3-attributable deaths were projected to occur. These projections decreased to an estimated 15 000 (95% CI, 10 000-20 000) PM2.5-attributable deaths and 640 (95% CI, 340-940) O3-attributable deaths when simulated using a future emission inventory that accounted for reduced anthropogenic emissions. Conclusions and Relevance: These findings suggest that reducing future air pollutant emissions could also reduce the climate-driven increase in deaths associated with air pollution by hundreds to thousands.
Authors: Christopher G Nolte; Tanya L Spero; Jared H Bowden; Megan S Mallard; Patrick D Dolwick Journal: Atmos Chem Phys Date: 2018 Impact factor: 6.133
Authors: Arlene M Fiore; Vaishali Naik; Dominick V Spracklen; Allison Steiner; Nadine Unger; Michael Prather; Dan Bergmann; Philip J Cameron-Smith; Irene Cionni; William J Collins; Stig Dalsøren; Veronika Eyring; Gerd A Folberth; Paul Ginoux; Larry W Horowitz; Béatrice Josse; Jean-François Lamarque; Ian A MacKenzie; Tatsuya Nagashima; Fiona M O'Connor; Mattia Righi; Steven T Rumbold; Drew T Shindell; Ragnhild B Skeie; Kengo Sudo; Sophie Szopa; Toshihiko Takemura; Guang Zeng Journal: Chem Soc Rev Date: 2012-08-06 Impact factor: 54.564
Authors: Pattanun Achakulwisut; Susan C Anenberg; James E Neumann; Stefani L Penn; Natalie Weiss; Allison Crimmins; Neal Fann; Jeremy Martinich; Henry Roman; Loretta J Mickley Journal: Geohealth Date: 2019
Authors: Philip E Morefield; Neal Fann; Anne Grambsch; William Raich; Christopher P Weaver Journal: Int J Environ Res Public Health Date: 2018-11-01 Impact factor: 3.390
Authors: Richard Burnett; Hong Chen; Mieczysław Szyszkowicz; Neal Fann; Bryan Hubbell; C Arden Pope; Joshua S Apte; Michael Brauer; Aaron Cohen; Scott Weichenthal; Jay Coggins; Qian Di; Bert Brunekreef; Joseph Frostad; Stephen S Lim; Haidong Kan; Katherine D Walker; George D Thurston; Richard B Hayes; Chris C Lim; Michelle C Turner; Michael Jerrett; Daniel Krewski; Susan M Gapstur; W Ryan Diver; Bart Ostro; Debbie Goldberg; Daniel L Crouse; Randall V Martin; Paul Peters; Lauren Pinault; Michael Tjepkema; Aaron van Donkelaar; Paul J Villeneuve; Anthony B Miller; Peng Yin; Maigeng Zhou; Lijun Wang; Nicole A H Janssen; Marten Marra; Richard W Atkinson; Hilda Tsang; Thuan Quoc Thach; John B Cannon; Ryan T Allen; Jaime E Hart; Francine Laden; Giulia Cesaroni; Francesco Forastiere; Gudrun Weinmayr; Andrea Jaensch; Gabriele Nagel; Hans Concin; Joseph V Spadaro Journal: Proc Natl Acad Sci U S A Date: 2018-09-04 Impact factor: 11.205
Authors: Nicholas J Nassikas; Elizabeth A W Chan; Christopher G Nolte; Henry A Roman; Niamh Micklewhite; Patrick L Kinney; E Jane Carter; Neal L Fann Journal: Air Qual Atmos Health Date: 2022-01-10 Impact factor: 3.763
Authors: Christopher G Nolte; Tanya L Spero; Jared H Bowden; Marcus C Sarofim; Jeremy Martinich; Megan S Mallard Journal: J Air Waste Manag Assoc Date: 2021-10 Impact factor: 2.636
Authors: Neal Fann; Evan Coffman; Melanie Jackson; Iny Jhun; Archana P Lamichhane; Christopher G Nolte; Henry Roman; Jason D Sacks Journal: Environ Sci Technol Date: 2021-12-29 Impact factor: 11.357
Authors: Kevin R Cromar; Susan C Anenberg; John R Balmes; Allen A Fawcett; Marya Ghazipura; Julia M Gohlke; Masahiro Hashizume; Peter Howard; Eric Lavigne; Karen Levy; Jaime Madrigano; Jeremy A Martinich; Erin A Mordecai; Mary B Rice; Shubhayu Saha; Noah C Scovronick; Fatih Sekercioglu; Erik R Svendsen; Benjamin F Zaitchik; Gary Ewart Journal: Ann Am Thorac Soc Date: 2022-07
Authors: James E Neumann; Meredith Amend; Susan Anenberg; Patrick L Kinney; Marcus Sarofim; Jeremy Martinich; Julia Lukens; Jun-Wei Xu; Henry Roman Journal: Environ Res Lett Date: 2021-03-08 Impact factor: 6.793
Authors: Marcus C Sarofim; Jeremy Martinich; James E Neumann; Jacqueline Willwerth; Zoe Kerrich; Michael Kolian; Charles Fant; Corinne Hartin Journal: Clim Change Date: 2021-03-19 Impact factor: 4.743