uri,href,identifier,attrs.Abstract,"attrs.Accession Number",attrs.Author,"attrs.Author Address",attrs.DOI,"attrs.Database Provider",attrs.Date,"attrs.EPub Date",attrs.ISSN,attrs.Issue,attrs.Journal,attrs.Keywords,attrs.Language,attrs.NIHMSID,"attrs.Name of Database",attrs.Notes,attrs.PMCID,attrs.Pages,"attrs.Research Notes",attrs.Title,attrs.Volume,attrs.Year,attrs._record_number,attrs._uuid,attrs.reftype,child_publication
/reference/93b59cc9-ade0-45fe-9f08-79b0c00da931,https://data.globalchange.gov/reference/93b59cc9-ade0-45fe-9f08-79b0c00da931,93b59cc9-ade0-45fe-9f08-79b0c00da931,"OBJECTIVES: Many public health adaptation strategies have been identified in response to climate change. This report reviews current literature on health co-benefits and risks of these strategies to gain a better understanding of how they may affect health. METHODS: A literature review was conducted electronically using English language literature from January 2000 to March 2012. Of 812 articles identified, 22 peer-reviewed articles that directly addressed health co-benefits or risks of adaptation were included in the review. RESULTS: The co-benefits and risks identified in the literature most commonly relate to improvements in health associated with adaptation actions that affect social capital and urban design. Health co-benefits of improvements in social capital have positive influences on mental health, independently of other determinants. Risks included reinforcing existing misconceptions regarding health. Health co-benefits of urban design strategies included reduced obesity, cardiovascular disease and improved mental health through increased physical activity, cooling spaces (e.g., shaded areas), and social connectivity. Risks included pollen allergies with increased urban green space, and adverse health effects from heat events through the use of air conditioning. CONCLUSIONS: Due to the current limited understanding of the full impacts of the wide range of existing climate change adaptation strategies, further research should focus on both unintended positive and negative consequences of public health adaptation.",23111371,"Cheng, J. J.; Berry, P.","Public Health and Preventive Medicine Program, Department of Clinical Epidemiology and Biostatistics, McMaster University, 1280 Main Street West, HSC2C2, Hamilton, ON, L8S 4K1, Canada. june.cheng@medportal.ca",10.1007/s00038-012-0422-5,"CCII PubMed NLM",Apr,2012/11/01,"1661-8564 (Electronic)
1661-8556 (Linking)",2,"International Journal of Public Health","Adaptation, Physiological; Climate Change; Humans; Public Health; Risk Factors",eng," NIEHS"," ","Cheng, June J
Berry, Peter
Review
Switzerland
Int J Public Health. 2013 Apr;58(2):305-11. doi: 10.1007/s00038-012-0422-5. Epub 2012 Oct 31.",3607711,305-311,"CCII Unique ","Health co-benefits and risks of public health adaptation strategies to climate change: A review of current literature",58,2013,4223,93b59cc9-ade0-45fe-9f08-79b0c00da931,"Journal Article",/article/10.1007/s00038-012-0422-5
/reference/93e74b72-dff9-4cc6-96e2-2dfd76d9c418,https://data.globalchange.gov/reference/93e74b72-dff9-4cc6-96e2-2dfd76d9c418,93e74b72-dff9-4cc6-96e2-2dfd76d9c418,"Wildland fire management has reached a crossroads. Current perspectives are not capable of answering interdisciplinary adaptation and mitigation challenges posed by increases in wildfire risk to human populations and the need to reintegrate fire as a vital landscape process. Fire science has been, and continues to be, performed in isolated “silos,” including institutions (e.g., agencies versus universities), organizational structures (e.g., federal agency mandates versus local and state procedures for responding to fire), and research foci (e.g., physical science, natural science, and social science). These silos tend to promote research, management, and policy that focus only on targeted aspects of the “wicked” wildfire problem. In this article, we provide guiding principles to bridge diverse fire science efforts to advance an integrated agenda of wildfire research that can help overcome disciplinary silos and provide insight on how to build fire-resilient communities.",,"Smith, Alistair M. S.; Kolden, Crystal A.; Paveglio, Travis B.; Cochrane, Mark A.; Bowman, David M. J. S.; Moritz, Max A.; Kliskey, Andrew D.; Alessa, Lilian; Hudak, Andrew T.; Hoffman, Chad M.; Lutz, James A.; Queen, Lloyd P.; Goetz, Scott J.; Higuera, Philip E.; Boschetti, Luigi; Flannigan, Mike; Yedinak, Kara M.; Watts, Adam C.; Strand, Eva K.; van Wagtendonk, Jan W.; Anderson, John W.; Stocks, Brian J.; Abatzoglou, John T.",,10.1093/biosci/biv182,,,,0006-3568,2,BioScience,,,,,,,130-146,,"The science of firescapes: Achieving fire-resilient communities",66,2016,21402,93e74b72-dff9-4cc6-96e2-2dfd76d9c418,"Journal Article",/article/10.1093/biosci/biv182
/reference/94a8514e-063e-45ef-b893-11c82b49a597,https://data.globalchange.gov/reference/94a8514e-063e-45ef-b893-11c82b49a597,94a8514e-063e-45ef-b893-11c82b49a597,,,"Church, J.A.
White, N.J.",,10.1007/s10712-011-9119-1,,,,0169-3298,4-5,"Surveys in Geophysics",,,,,,,585-602,,"Sea-level rise from the late 19th to the early 21st century",32,2011,1512,94a8514e-063e-45ef-b893-11c82b49a597,"Journal Article",/article/10.1007/s10712-011-9119-1
/reference/953476ae-1357-48a5-99d8-1daf963f0a3c,https://data.globalchange.gov/reference/953476ae-1357-48a5-99d8-1daf963f0a3c,953476ae-1357-48a5-99d8-1daf963f0a3c,,,"Redsteer, M.H.
Bogle, R.C.
Vogel, J.M.",,,,,,,,,,,,,,,,,"Monitoring and Analysis of Sand Dune Movement and Growth on the Navajo Nation, Southwestern United States. Fact Sheet Number 3085",,2011,2597,953476ae-1357-48a5-99d8-1daf963f0a3c,Report,/report/usgs-factsheet-2011-3085
/reference/966bf116-8d6d-41f2-96be-4b66d3e729db,https://data.globalchange.gov/reference/966bf116-8d6d-41f2-96be-4b66d3e729db,966bf116-8d6d-41f2-96be-4b66d3e729db,,,"Kunkel, K. E.
Stevens, L. E.
Stevens, S. E.
Sun, L.
Janssen, E.
Wuebbles, D.
Redmond, K.T.
Dobson, J.G.",,,,,,,,,,,,,,,87,,"Regional Climate Trends and Scenarios for the U.S. National Climate Assessment: Part 5. Climate of the Southwest U.S. NOAA Technical Report NESDIS 142-5",,2013,1413,966bf116-8d6d-41f2-96be-4b66d3e729db,"Government Document",/report/noaa-techreport-nesdis-142-5
/reference/9711f2e3-f3b1-4d25-bc0a-47fd17b56e41,https://data.globalchange.gov/reference/9711f2e3-f3b1-4d25-bc0a-47fd17b56e41,9711f2e3-f3b1-4d25-bc0a-47fd17b56e41,,,,,,,,,,,,,,,,,,,,"Assessment of Climate Change in the Southwest United States: A Report Prepared for the National Climate Assessment",,2013,119,9711f2e3-f3b1-4d25-bc0a-47fd17b56e41,"Edited Book",/book/c9625c65-c20f-4163-87fe-cebf734f7836
/reference/97410dfa-e13f-46b8-816b-23f0c038f22b,https://data.globalchange.gov/reference/97410dfa-e13f-46b8-816b-23f0c038f22b,97410dfa-e13f-46b8-816b-23f0c038f22b,,,"State of California,",,,,,,,,,,,,,,,,,"A Proclamation of a State of Emergency [April 25, 2014]",,2014,23919,97410dfa-e13f-46b8-816b-23f0c038f22b,"Web Page",/webpage/4550555f-553a-422e-badc-85b0e4156e8b
/reference/9743c446-fef0-44f4-82bd-7f2ff1614205,https://data.globalchange.gov/reference/9743c446-fef0-44f4-82bd-7f2ff1614205,9743c446-fef0-44f4-82bd-7f2ff1614205,,,"Tingley, Morgan W.; Koo, Michelle S.; Moritz, Craig; Rush, Andrew C.; Beissinger, Steven R.",,10.1111/j.1365-2486.2012.02784.x,,,,1365-2486,11,"Global Change Biology","birds; California; climate change; elevational range shift; occupancy models; precipitation; Sierra Nevada",,,,,,3279-3290,,"The push and pull of climate change causes heterogeneous shifts in avian elevational ranges",18,2012,23871,9743c446-fef0-44f4-82bd-7f2ff1614205,"Journal Article",/article/10.1111/j.1365-2486.2012.02784.x
/reference/97529f0e-77d2-41eb-93e9-7196eb3a42cd,https://data.globalchange.gov/reference/97529f0e-77d2-41eb-93e9-7196eb3a42cd,97529f0e-77d2-41eb-93e9-7196eb3a42cd,,,"National Park Service",,,,,,,,,,,,,,,104,,"A Climate-Smart Resource Stewardship Strategy for Sequoia and Kings Canyon National Parks",,2017,26740,,Report,/report/climate-smart-resource-stewardship-strategy-sequoia-kings-canyon-national-parks
/reference/9871290a-65c9-435f-9ad0-00514a8a08e6,https://data.globalchange.gov/reference/9871290a-65c9-435f-9ad0-00514a8a08e6,9871290a-65c9-435f-9ad0-00514a8a08e6,"Designing climate-related research so that study results will be useful to natural resource managers is a unique challenge. While decision makers increasingly recognize the need to consider climate change in their resource management plans, and climate scientists recognize the importance of providing locally-relevant climate data and projections, there often remains a gap between management needs and the information that is available or is being collected. We used decision analysis concepts to bring decision-maker and stakeholder perspectives into the applied research planning process. In 2009 we initiated a series of studies on the impacts of climate change in the Yakima River Basin (YRB) with a four-day stakeholder workshop, bringing together managers, stakeholders, and scientists to develop an integrated conceptual model of climate change and climate change impacts in the YRB. The conceptual model development highlighted areas of uncertainty that limit the understanding of the potential impacts of climate change and decision alternatives by those who will be most directly affected by those changes, and pointed to areas where additional study and engagement of stakeholders would be beneficial. The workshop and resulting conceptual model highlighted the importance of numerous different outcomes to stakeholders in the basin, including social and economic outcomes that go beyond the physical and biological outcomes typically reported in climate impacts studies. Subsequent studies addressed several of those areas of uncertainty, including changes in water temperatures, habitat quality, and bioenergetics of salmonid populations.",,"Jenni, K.; Graves, D.; Hardiman, J.; Hatten, J.; Mastin, M.; Mesa, M.; Montag, J.; Nieman, T.; Voss, F.; Maule, A.",,10.1007/s10584-013-0806-4,,"May 01",,1573-1480,1,"Climatic Change",,,,,,,371-384,,"Identifying stakeholder-relevant climate change impacts: A case study in the Yakima River Basin, Washington, USA",124,2014,23793,9871290a-65c9-435f-9ad0-00514a8a08e6,"Journal Article",/article/10.1007/s10584-013-0806-4
/reference/98957f73-e40a-4a1e-b48d-01108d939123,https://data.globalchange.gov/reference/98957f73-e40a-4a1e-b48d-01108d939123,98957f73-e40a-4a1e-b48d-01108d939123,,,"Donatuto, Jamie; Grossman, Eric E.; Konovsky, John; Grossman, Sarah; Campbell, Larry W.",,10.1080/08920753.2014.923140,,,,1521-0421,4,"Coastal Management",,,,,,,355-373,,"Indigenous community health and climate change: Integrating biophysical and social science indicators",42,2014,17838,98957f73-e40a-4a1e-b48d-01108d939123,"Journal Article",/article/10.1080/08920753.2014.923140
/reference/99baa64e-2877-4db9-b257-3f41149e73fe,https://data.globalchange.gov/reference/99baa64e-2877-4db9-b257-3f41149e73fe,99baa64e-2877-4db9-b257-3f41149e73fe,,,"Garfin, Gregg
Franco, Guido
Blanco, Hilda
Comrie, Andrew
Gonzalez, Patrick
Piechota, Thomas
Smyth, Rebecca
Waskom, Reagan",,10.7930/J08G8HMN,,,,,,,,,,,,,462-486,,"Ch. 20: Southwest",,2014,4730,99baa64e-2877-4db9-b257-3f41149e73fe,"Book Section",/report/nca3/chapter/southwest
/reference/99e25417-f6c0-49f1-87cd-e9af689f3cff,https://data.globalchange.gov/reference/99e25417-f6c0-49f1-87cd-e9af689f3cff,99e25417-f6c0-49f1-87cd-e9af689f3cff,,,"Brady, Riley X.; Alexander, Michael A.; Lovenduski, Nicole S.; Rykaczewski, Ryan R.",,10.1002/2017GL072945,,,,1944-8007,10,"Geophysical Research Letters","coastal upwelling; internal variability; California Current; Earth System Model; model ensemble; 1626 Global climate models; 4215 Climate and interannual variability; 4279 Upwelling and convergences; 4516 Eastern boundary currents",,,,,,5044-5052,,"Emergent anthropogenic trends in California Current upwelling",44,2017,21089,99e25417-f6c0-49f1-87cd-e9af689f3cff,"Journal Article",/article/10.1002/2017GL072945
/reference/9b2c26f4-4e84-427b-9f4e-4265a1f86fe8,https://data.globalchange.gov/reference/9b2c26f4-4e84-427b-9f4e-4265a1f86fe8,9b2c26f4-4e84-427b-9f4e-4265a1f86fe8,,,"Young, Allison M.; Skelly, Klint T.; Cordeira, Jason M.",,10.1002/2017GL073077,,,,1944-8007,7,"Geophysical Research Letters","atmospheric river; flood; flash flood; debris flow; 1840 Hydrometeorology; 1821 Floods; 1817 Extreme events; 1854 Precipitation; 3364 Synoptic-scale meteorology",,,,,,3393-3401,,"High-impact hydrologic events and atmospheric rivers in California: An investigation using the NCEI Storm Events Database",44,2017,23891,9b2c26f4-4e84-427b-9f4e-4265a1f86fe8,"Journal Article",/article/10.1002/2017GL073077
/reference/9bb5fdef-86ff-4f8f-bf28-e5694c6fa104,https://data.globalchange.gov/reference/9bb5fdef-86ff-4f8f-bf28-e5694c6fa104,9bb5fdef-86ff-4f8f-bf28-e5694c6fa104,"Climate change is an enormous challenge for our communities, our country, and our world. Recently much attention has been paid to the physical impacts of climate change, including extreme heat events, droughts, extreme storms, and rising sea levels. However, much less attention has been paid to the psychological impacts. This article examines the likely psychological impacts of climate change, including anxiety, stress, and depression; increases in violence and aggression; and loss of community identity. Nurses can play a vital role in local and regional climate strategies by preparing their patients, health care facilities, and communities to effectively address the anticipated mental health impacts of climate change.",,"Trombley, Janna; Chalupka, Stephanie; Anderko, Laura",,10.1097/01.NAJ.0000515232.51795.fa,,,,0002-936X,4,"AJN The American Journal of Nursing","climate change; disasters; extreme weather; mental health; preparedness; psychological distress; resilience",,,,,,44-52,,"Climate change and mental health",117,2017,23874,9bb5fdef-86ff-4f8f-bf28-e5694c6fa104,"Journal Article",/article/10.1097/01.NAJ.0000515232.51795.fa
/reference/9c23a870-58cf-49f6-9c6f-01cb94e4bb5a,https://data.globalchange.gov/reference/9c23a870-58cf-49f6-9c6f-01cb94e4bb5a,9c23a870-58cf-49f6-9c6f-01cb94e4bb5a,,WOS:000262587900047,"Van Mantgem, P. J.
Stephenson, N. L.
Byrne, J. C.
Daniels, L. D.
Franklin, J. F.
Fule, P. Z.
Harmon, M. E.
Larson, A. J.
Smith, J. M.
Taylor, A. H.
Veblen, T. T.",,10.1126/science.1165000,,Jan,,0036-8075,5913,Science,,,,,,,521-524,,"Widespread increase of tree mortality rates in the western United States",323,2009,3265,9c23a870-58cf-49f6-9c6f-01cb94e4bb5a,"Journal Article",/article/10.1126/science.1165000
/reference/9d8a98fa-0338-486a-b902-cd02d43cae87,https://data.globalchange.gov/reference/9d8a98fa-0338-486a-b902-cd02d43cae87,9d8a98fa-0338-486a-b902-cd02d43cae87,,,"Bureau of Reclamation,",,,,,,,,,,,,,,,140,,"West-wide climate risk assessment: Hydroclimate projections",,2016,26400,9d8a98fa-0338-486a-b902-cd02d43cae87,Report,/report/west-wide-climate-risk-assessment-hydroclimate-projections
/reference/9def246f-d97d-4cda-8794-78ceefe6b8da,https://data.globalchange.gov/reference/9def246f-d97d-4cda-8794-78ceefe6b8da,9def246f-d97d-4cda-8794-78ceefe6b8da,,,"Tong, Daniel Q.; Wang, Julian X. L.; Gill, Thomas E.; Lei, Hang; Wang, Binyu",,10.1002/2017GL073524,,,,1944-8007,9,"Geophysical Research Letters","dust; Valley fever; climate; air quality; aerosol; health; 0305 Aerosols and particles; 0360 Radiation: transmission and scattering; 1616 Climate variability; 1630 Impacts of global change",,,,,,4304-4312,,"Intensified dust storm activity and Valley fever infection in the southwestern United States",44,2017,22043,9def246f-d97d-4cda-8794-78ceefe6b8da,"Journal Article",/article/10.1002/2017GL073524
/reference/9f272ed1-62dd-4393-89d3-f0d8b0dcb7a6,https://data.globalchange.gov/reference/9f272ed1-62dd-4393-89d3-f0d8b0dcb7a6,9f272ed1-62dd-4393-89d3-f0d8b0dcb7a6,,,"Cole, Kenneth L.; Ironside, Kirsten; Eischeid, Jon; Garfin, Gregg; Duffy, Phillip B.; Toney, Chris",,10.1890/09-1800.1,,,,1939-5582,1,"Ecological Applications","climate change; climate effects modeling; extinct seed vectors; Joshua tree; Mohave Desert; plant migration; Yucca brevifolia",,,,,,137-149,,"Past and ongoing shifts in Joshua tree distribution support future modeled range contraction",21,2011,23747,9f272ed1-62dd-4393-89d3-f0d8b0dcb7a6,"Journal Article",/article/10.1890/09-1800.1
/reference/9f637046-58b9-4716-82e6-afbd33fe4fa8,https://data.globalchange.gov/reference/9f637046-58b9-4716-82e6-afbd33fe4fa8,9f637046-58b9-4716-82e6-afbd33fe4fa8,"The atmospheric and oceanic causes of North American droughts are examined using observations and ensemble climate simulations. The models indicate that oceanic forcing of annual mean precipitation variability accounts for up to 40% of total variance in northeastern Mexico, the southern Great Plains, and the Gulf Coast states but less than 10% in central and eastern Canada. Observations and models indicate robust tropical Pacific and tropical North Atlantic forcing of annual mean precipitation and soil moisture with the most heavily influenced areas being in southwestern North America and the southern Great Plains. In these regions, individual wet and dry years, droughts, and decadal variations are well reproduced in atmosphere models forced by observed SSTs. Oceanic forcing was important in causing multiyear droughts in the 1950s and at the turn of the twenty-first century, although a similar ocean configuration in the 1970s was not associated with drought owing to an overwhelming influence of internal atmospheric variability. Up to half of the soil moisture deficits during severe droughts in the southeast United States in 2000, Texas in 2011, and the central Great Plains in 2012 were related to SST forcing, although SST forcing was an insignificant factor for northern Great Plains drought in 1988. During the early twenty-first century, natural decadal swings in tropical Pacific and North Atlantic SSTs have contributed to a dry regime for the United States. Long-term changes caused by increasing trace gas concentrations are now contributing to a modest signal of soil moisture depletion, mainly over the U.S. Southwest, thereby prolonging the duration and severity of naturally occurring droughts.",,"Seager, Richard; Martin Hoerling",,10.1175/jcli-d-13-00329.1,,,,,12,"Journal of Climate","North America,Atmosphere-ocean interaction,Climate variability,Hydrometeorology",,,,,,4581-4606,,"Atmosphere and ocean origins of North American droughts",27,2014,23852,9f637046-58b9-4716-82e6-afbd33fe4fa8,"Journal Article",/article/10.1175/jcli-d-13-00329.1
/reference/a073cf8e-8d74-4f11-bfe2-d3494b9bcc7a,https://data.globalchange.gov/reference/a073cf8e-8d74-4f11-bfe2-d3494b9bcc7a,a073cf8e-8d74-4f11-bfe2-d3494b9bcc7a,,,"Allen, Craig D.; Breshears, David D.; McDowell, Nate G.",,10.1890/ES15-00203.1,,,,2150-8925,8,Ecosphere,"carbon starvation; climate change; CO2 fertilization; drought; ESA Centennial Paper; extreme events; forest die-off; forests; hydraulic failure; insect pests; pathogens; tree mortality; woodlands",,,,,,1-55,,"On underestimation of global vulnerability to tree mortality and forest die-off from hotter drought in the Anthropocene",6,2015,23658,a073cf8e-8d74-4f11-bfe2-d3494b9bcc7a,"Journal Article",/article/10.1890/ES15-00203.1
/reference/a09ea040-c665-4178-bb8f-f666e3954516,https://data.globalchange.gov/reference/a09ea040-c665-4178-bb8f-f666e3954516,a09ea040-c665-4178-bb8f-f666e3954516,,,"Moran, Matthew D.; Taylor, Nathan T.; Mullins, Tabitha F.; Sardar, Sehrish S.; McClung, Maureen R.",,10.1002/fee.1492,,,,1540-9309,5,"Frontiers in Ecology and the Environment",,,,,,,237-242,,"Land-use and ecosystem services costs of unconventional US oil and gas development",15,2017,23830,a09ea040-c665-4178-bb8f-f666e3954516,"Journal Article",/article/10.1002/fee.1492
/reference/a108aef4-febe-4b68-95d4-79d719d5631f,https://data.globalchange.gov/reference/a108aef4-febe-4b68-95d4-79d719d5631f,a108aef4-febe-4b68-95d4-79d719d5631f,,,"Montilla-López, Nazaret M.; Gutiérrez-Martín, Carlos; Gómez-Limón, José A.",,10.3390/w8100466,,,,2073-4441,10,Water,,,,,,,466,,"Water banks: What have we learnt from the international experience?",8,2016,23829,a108aef4-febe-4b68-95d4-79d719d5631f,"Journal Article",/article/10.3390/w8100466
/reference/a1aee4ba-d4fc-4f92-a74a-e37189c138b5,https://data.globalchange.gov/reference/a1aee4ba-d4fc-4f92-a74a-e37189c138b5,a1aee4ba-d4fc-4f92-a74a-e37189c138b5,,,"Griggs, Gary; Árvai, Joseph; Cayan, Dan; DeConto, Robert; Fox, Jenn; Fricker, Helen Amanda; Kopp, Robert E.; Tebaldi, Claudia; Whiteman, Elizabeth A.",,,,,,,,,,,,,,,71,,"Rising Seas in California: An Update on Sea-Level Rise Science",,2017,23950,a1aee4ba-d4fc-4f92-a74a-e37189c138b5,Report,/report/rising-seas-california-an-update-on-sea-level-rise-science