uri,href,identifier,attrs.Author,attrs.DOI,attrs.ISSN,attrs.Journal,attrs.Keywords,attrs.Pages,attrs.Title,attrs.Volume,attrs.Year,attrs.\.reference_type,attrs._record_number,attrs._uuid,attrs.reftype,child_publication
/reference/cc7159e1-bdd7-450e-b4c6-a943fc153351,https://data.globalchange.gov/reference/cc7159e1-bdd7-450e-b4c6-a943fc153351,cc7159e1-bdd7-450e-b4c6-a943fc153351,"Fisk, William J.",10.1016/j.buildenv.2014.12.024,0360-1323,"Building and Environment","Building; Climate change; Health; Indoor air quality; Indoor environmental quality; Mitigation",70-80,"Review of some effects of climate change on indoor environmental quality and health and associated no-regrets mitigation measures",86,2015,0,18473,cc7159e1-bdd7-450e-b4c6-a943fc153351,"Journal Article",/article/10.1016/j.buildenv.2014.12.024
/reference/ccd5ec24-c9a9-4e7d-9ae4-b51314ef0e03,https://data.globalchange.gov/reference/ccd5ec24-c9a9-4e7d-9ae4-b51314ef0e03,ccd5ec24-c9a9-4e7d-9ae4-b51314ef0e03,"Abel, David; Holloway, Tracey; Kladar, Ryan M.; Meier, Paul; Ahl, Doug; Harkey, Monica; Patz, Jonathan",10.1021/acs.est.6b06201,0013-936X,"Environmental Science & Technology",,5838-5846,"Response of power plant emissions to ambient temperature in the eastern United States",51,2017,,24279,ccd5ec24-c9a9-4e7d-9ae4-b51314ef0e03,"Journal Article",/article/10.1021/acs.est.6b06201
/reference/ce66dd8b-5138-4f60-93d8-7b2e23a8b715,https://data.globalchange.gov/reference/ce66dd8b-5138-4f60-93d8-7b2e23a8b715,ce66dd8b-5138-4f60-93d8-7b2e23a8b715,"Wilson, Ander; Rappold, Ana G.; Neas, Lucas M.; Reich, Brian J.",10.1214/14-AOAS754,1932-6157,"Annals of Applied Statistics","Air pollution; monotone regression; mortality; ozone-temperature interaction; semi-parametric regression; spatial modeling",1728-1749,"Modeling the effect of temperature on ozone-related mortality",8,2014,,24223,ce66dd8b-5138-4f60-93d8-7b2e23a8b715,"Journal Article",/article/10.1214/14-AOAS754
/reference/cef909e2-e454-43ad-b271-e96fe19a5276,https://data.globalchange.gov/reference/cef909e2-e454-43ad-b271-e96fe19a5276,cef909e2-e454-43ad-b271-e96fe19a5276,"Turner, A. J.; Fiore, A. M.; Horowitz, L. W.; Bauer, M.",10.5194/acp-13-565-2013,1680-7324,"Atmospheric Chemistry and Physics",,565-578,"Summertime cyclones over the Great Lakes Storm Track from 1860–2100: Variability, trends, and association with ozone pollution",13,2013,,24233,cef909e2-e454-43ad-b271-e96fe19a5276,"Journal Article",/article/10.5194/acp-13-565-2013
/reference/d3f82686-12ef-4e1e-9a15-cf89236a53a8,https://data.globalchange.gov/reference/d3f82686-12ef-4e1e-9a15-cf89236a53a8,d3f82686-12ef-4e1e-9a15-cf89236a53a8,"Schelegle, Edward S.; Christopher A. Morales; William F. Walby; Susan Marion; Roblee P. Allen",10.1164/rccm.200809-1484OC,,"American Journal of Respiratory and Critical Care Medicine","ozone,clinical study,exposure assessment,human",265-272,"6.6-hour inhalation of ozone concentrations from 60 to 87 parts per billion in healthy humans",180,2009,,24242,d3f82686-12ef-4e1e-9a15-cf89236a53a8,"Journal Article",/article/10.1164/rccm.200809-1484OC
/reference/d4eed57d-04b4-4b05-a4aa-352bf223951f,https://data.globalchange.gov/reference/d4eed57d-04b4-4b05-a4aa-352bf223951f,d4eed57d-04b4-4b05-a4aa-352bf223951f,"Gao, Jinghong; Kovats, Sari; Vardoulakis, Sotiris; Wilkinson, Paul; Woodward, Alistair; Li, Jing; Gu, Shaohua; Liu, Xiaobo; Wu, Haixia; Wang, Jun; Song, Xiaoqin; Zhai, Yunkai; Zhao, Jie; Liu, Qiyong",10.1016/j.scitotenv.2018.01.193,0048-9697,"Science of The Total Environment","Air pollution; Climate change; Greenhouse gas emissions; Health co-benefits; Mitigation; Uncertainty",388-402,"Public health co-benefits of greenhouse gas emissions reduction: A systematic review",627,2018,,25134,d4eed57d-04b4-4b05-a4aa-352bf223951f,"Journal Article",/article/10.1016/j.scitotenv.2018.01.193
/reference/d96a729a-a5db-4318-8f52-78f6031b42fd,https://data.globalchange.gov/reference/d96a729a-a5db-4318-8f52-78f6031b42fd,d96a729a-a5db-4318-8f52-78f6031b42fd,"Barbero, R.; J. T. Abatzoglou; E. A. Steel; Narasimhan K. Larkin",10.1088/1748-9326/9/12/124009,1748-9326,"Environmental Research Letters",,124009,"Modeling very large-fire occurrences over the continental United States from weather and climate forcing",9,2014,,24275,d96a729a-a5db-4318-8f52-78f6031b42fd,"Journal Article",/article/10.1088/1748-9326/9/12/124009
/reference/da337e51-3cba-4587-8958-1c991952349c,https://data.globalchange.gov/reference/da337e51-3cba-4587-8958-1c991952349c,da337e51-3cba-4587-8958-1c991952349c,"Lam, Y. F.; Fu, J. S.; Wu, S.; Mickley, L. J.",10.5194/acp-11-4789-2011,1680-7324,"Atmospheric Chemistry and Physics",,4789-4806,"Impacts of future climate change and effects of biogenic emissions on surface ozone and particulate matter concentrations in the United States",11,2011,,24255,da337e51-3cba-4587-8958-1c991952349c,"Journal Article",/article/10.5194/acp-11-4789-2011
/reference/dd3e0e92-583c-44d5-9bb8-03e1057e605f,https://data.globalchange.gov/reference/dd3e0e92-583c-44d5-9bb8-03e1057e605f,dd3e0e92-583c-44d5-9bb8-03e1057e605f,"Schnell, Jordan L.; Prather, Michael J.",10.1073/pnas.1614453114,,"Proceedings of the National Academy of Sciences of the United States of America",,2854-2859,"Co-occurrence of extremes in surface ozone, particulate matter, and temperature over eastern North America",114,2017,,24241,dd3e0e92-583c-44d5-9bb8-03e1057e605f,"Journal Article",/article/10.1073/pnas.1614453114
/reference/dd4ad6ad-d135-4c25-9fe0-e462253fcf01,https://data.globalchange.gov/reference/dd4ad6ad-d135-4c25-9fe0-e462253fcf01,dd4ad6ad-d135-4c25-9fe0-e462253fcf01,"Wolf, J.
O’Neill, N.R.
Rogers, C.A.
Muilenberg, M.L.
Ziska, L.H.",10.1289/ehp.0901867,,"Environmental Health Perspectives",,1223-1228,"Elevated atmospheric carbon dioxide concentrations amplify Alternaria alternata sporulation and total antigen production",118,2010,0,3456,dd4ad6ad-d135-4c25-9fe0-e462253fcf01,"Journal Article",/article/10.1289/ehp.0901867
/reference/de4a77df-03ba-4319-a13f-7fdefbb353a5,https://data.globalchange.gov/reference/de4a77df-03ba-4319-a13f-7fdefbb353a5,de4a77df-03ba-4319-a13f-7fdefbb353a5,"Abatzoglou, John T.; Williams, A. Park",10.1073/pnas.1607171113,,"Proceedings of the National Academy of Sciences of the United States of America",,11770-11775,"Impact of anthropogenic climate change on wildfire across western US forests",113,2016,0,20416,de4a77df-03ba-4319-a13f-7fdefbb353a5,"Journal Article",/article/10.1073/pnas.1607171113
/reference/e00fb4e2-6406-40be-90f8-071dfc43cca3,https://data.globalchange.gov/reference/e00fb4e2-6406-40be-90f8-071dfc43cca3,e00fb4e2-6406-40be-90f8-071dfc43cca3,EPA,,,,,1251,"Integrated Science Assessment for Ozone and Related Photochemical Oxidants",,2013,10,18813,e00fb4e2-6406-40be-90f8-071dfc43cca3,Report,/report/epa-600-r-10-076f
/reference/e1e1f3a0-9fea-4ad2-a3af-575716f9849e,https://data.globalchange.gov/reference/e1e1f3a0-9fea-4ad2-a3af-575716f9849e,e1e1f3a0-9fea-4ad2-a3af-575716f9849e,"Westerling, A.L.
Hidalgo, H.G.
Cayan, D.R.
Swetnam, T.W.",10.1126/science.1128834,0036-8075,Science,"PONDEROSA PINE FORESTS; UNITED-STATES; VEGETATION DISTRIBUTION; CLIMATE-CHANGE; FIRE REGIMES; VARIABILITY; PERSPECTIVE; ECOSYSTEMS; ENSO",940-943,"Warming and earlier spring increase western U.S. forest wildfire activity",313,2006,0,3397,e1e1f3a0-9fea-4ad2-a3af-575716f9849e,"Journal Article",/article/10.1126/science.1128834
/reference/e92625ac-9348-4db7-ae87-b1f27ab954f6,https://data.globalchange.gov/reference/e92625ac-9348-4db7-ae87-b1f27ab954f6,e92625ac-9348-4db7-ae87-b1f27ab954f6,"EPA,",,,,,various,"2014 National Emissions Inventory, Version 1. Technical Support Document",,2016,10,25900,e92625ac-9348-4db7-ae87-b1f27ab954f6,Report,/report/2014-national-emissions-inventory-version-1-technical-support-document
/reference/ea8d831c-6b6b-4f8c-9b60-f17bab43660e,https://data.globalchange.gov/reference/ea8d831c-6b6b-4f8c-9b60-f17bab43660e,ea8d831c-6b6b-4f8c-9b60-f17bab43660e,"Balch, Jennifer K.; Bradley, Bethany A.; Abatzoglou, John T.; Nagy, R. Chelsea; Fusco, Emily J.; Mahood, Adam L.",10.1073/pnas.1617394114,,"Proceedings of the National Academy of Sciences of the United States of America",,2946-2951,"Human-started wildfires expand the fire niche across the United States",114,2017,,22012,ea8d831c-6b6b-4f8c-9b60-f17bab43660e,"Journal Article",/article/10.1073/pnas.1617394114
/reference/ebdc5b02-51f9-438e-aaf5-392da7e48283,https://data.globalchange.gov/reference/ebdc5b02-51f9-438e-aaf5-392da7e48283,ebdc5b02-51f9-438e-aaf5-392da7e48283,"Zhang, Yuqiang; Bowden, Jared H.; Adelman, Zachariah; Naik, Vaishali; Horowitz, Larry W.; Smith, Steven J.; West, Jason J.",10.5194/acp-16-9533-2016,1680-7324,"Atmospheric Chemistry and Physics",,9533-9548,"Co-benefits of global and regional greenhouse gas mitigation for US air quality in 2050",16,2016,,24218,ebdc5b02-51f9-438e-aaf5-392da7e48283,"Journal Article",/article/10.5194/acp-16-9533-2016
/reference/f4daa36c-4b3f-449a-8d03-94cdd39fe1eb,https://data.globalchange.gov/reference/f4daa36c-4b3f-449a-8d03-94cdd39fe1eb,f4daa36c-4b3f-449a-8d03-94cdd39fe1eb,"Keywood, Melita; Kanakidou, Maria; Stohl, Andreas; Dentener, Frank; Grassi, Giacomo; Meyer, C. P.; Torseth, Kjetil; Edwards, David; Thompson, Anne M.; Lohmann, Ulrike; Burrows, John",10.1080/10643389.2011.604248,1547-6537,"Critical Reviews in Environmental Science and Technology",,40-83,"Fire in the air: Biomass burning impacts in a changing climate",43,2013,0,18904,f4daa36c-4b3f-449a-8d03-94cdd39fe1eb,"Journal Article",/article/10.1080/10643389.2011.604248
/reference/f680e49e-d58f-45c2-8ad6-a7bc97c12ca0,https://data.globalchange.gov/reference/f680e49e-d58f-45c2-8ad6-a7bc97c12ca0,f680e49e-d58f-45c2-8ad6-a7bc97c12ca0,"Williams, A Park; Abatzoglou, John T",10.1007/s40641-016-0031-0,2198-6061,"Current Climate Change Reports",,1-14,"Recent advances and remaining uncertainties in resolving past and future climate effects on global fire activity",2,2016,,22662,f680e49e-d58f-45c2-8ad6-a7bc97c12ca0,"Journal Article",/article/10.1007/s40641-016-0031-0
/reference/f7ffc8dd-70ec-4779-817a-b2985c0779e7,https://data.globalchange.gov/reference/f7ffc8dd-70ec-4779-817a-b2985c0779e7,f7ffc8dd-70ec-4779-817a-b2985c0779e7,EPA,,,,,,"Integrated Science Assessment for Particulate Matter",,2009,10,18616,f7ffc8dd-70ec-4779-817a-b2985c0779e7,Report,/report/epa-600-r-08-139f
/reference/f89543d6-09bf-436c-8f7e-c0f908473457,https://data.globalchange.gov/reference/f89543d6-09bf-436c-8f7e-c0f908473457,f89543d6-09bf-436c-8f7e-c0f908473457,"Blando, James; Bielory, Leonard; Nguyen, Viann; Diaz, Rafael; Jeng, Hueiwang Anna",10.3390/atmos3010200,2073-4433,Atmosphere,,200-212,"Anthropogenic climate change and allergic diseases",3,2012,0,17657,f89543d6-09bf-436c-8f7e-c0f908473457,"Journal Article",/article/10.3390/atmos3010200
/reference/f9143a5a-8bb1-4d1f-a63f-d1a49588241b,https://data.globalchange.gov/reference/f9143a5a-8bb1-4d1f-a63f-d1a49588241b,f9143a5a-8bb1-4d1f-a63f-d1a49588241b,"Sarofim, Marcus C.; Waldhoff, Stephanie T.; Anenberg, Susan C.",10.1007/s10640-015-9937-6,1573-1502,"Environmental and Resource Economics",,45-63,"Valuing the ozone-related health benefits of methane emission controls",66,2017,,24243,f9143a5a-8bb1-4d1f-a63f-d1a49588241b,"Journal Article",/article/10.1007/s10640-015-9937-6
/reference/f9710d56-e7a2-4b57-98e9-abefcf53ff6e,https://data.globalchange.gov/reference/f9710d56-e7a2-4b57-98e9-abefcf53ff6e,f9710d56-e7a2-4b57-98e9-abefcf53ff6e,"Cottle, Paul; Strawbridge, Kevin; McKendry, Ian",10.1016/j.atmosenv.2014.03.005,1352-2310,"Atmospheric Environment","Lidar; Aerosols; Long range transport; Smoke; Air quality; 2012",71-77,"Long-range transport of Siberian wildfire smoke to British Columbia: Lidar observations and air quality impacts",90,2014,,24269,f9710d56-e7a2-4b57-98e9-abefcf53ff6e,"Journal Article",/article/10.1016/j.atmosenv.2014.03.005
/reference/f978dc0e-2a56-4bc9-9c67-d2f2a1de0914,https://data.globalchange.gov/reference/f978dc0e-2a56-4bc9-9c67-d2f2a1de0914,f978dc0e-2a56-4bc9-9c67-d2f2a1de0914,"D’Amato, G.; Cecchi, L.; D’Amato, M.; Liccardi, G.",,,"Journal of Investigational Allergology and Clinical Immunology",,95-102,"Urban air pollution and climate change as environmental risk factors of respiratory allergy: An update",20,2010,,24214,f978dc0e-2a56-4bc9-9c67-d2f2a1de0914,"Journal Article",/article/pmc-20461963
/reference/fa526617-d6bd-4dad-924a-ff93d72af612,https://data.globalchange.gov/reference/fa526617-d6bd-4dad-924a-ff93d72af612,fa526617-d6bd-4dad-924a-ff93d72af612,"Fiore, A. M.; Dentener, F. J.; Wild, O.; Cuvelier, C.; Schultz, M. G.; Hess, P.; Textor, C.; Schulz, M.; Doherty, R. M.; Horowitz, L. W.; MacKenzie, I. A.; Sanderson, M. G.; Shindell, D. T.; Stevenson, D. S.; Szopa, S.; Van Dingenen, R.; Zeng, G.; Atherton, C.; Bergmann, D.; Bey, I.; Carmichael, G.; Collins, W. J.; Duncan, B. N.; Faluvegi, G.; Folberth, G.; Gauss, M.; Gong, S.; Hauglustaine, D.; Holloway, T.; Isaksen, I. S. A.; Jacob, D. J.; Jonson, J. E.; Kaminski, J. W.; Keating, T. J.; Lupu, A.; Marmer, E.; Montanaro, V.; Park, R. J.; Pitari, G.; Pringle, K. J.; Pyle, J. A.; Schroeder, S.; Vivanco, M. G.; Wind, P.; Wojcik, G.; Wu, S.; Zuber, A.",10.1029/2008JD010816,,"Journal of Geophysical Research: Atmospheres",,D04301,"Multimodel estimates of intercontinental source-receptor relationships for ozone pollution",114,2009,,25895,fa526617-d6bd-4dad-924a-ff93d72af612,"Journal Article",/article/10.1029/2008JD010816
/reference/fa5efefc-806a-41e1-a0a2-90502ea74a0f,https://data.globalchange.gov/reference/fa5efefc-806a-41e1-a0a2-90502ea74a0f,fa5efefc-806a-41e1-a0a2-90502ea74a0f,"Thompson, Tammy M.; Rausch, Sebastian; Saari, Rebecca K.; Selin, Noelle E.",10.1038/nclimate2342,,"Nature Climate Change",,917-923,"A systems approach to evaluating the air quality co-benefits of US carbon policies",4,2014,,24236,fa5efefc-806a-41e1-a0a2-90502ea74a0f,"Journal Article",/article/10.1038/nclimate2342