---
- attributes: ~
caption: 'Major U.S. national and regional climate trends. Shaded areas are the U.S. regions defined in the 2014 NCA.dd5b893d-4462-4bb3-9205-67b532919566,bfc00315-ccea-4e7c-8a05-2650a07e4252'
chapter_identifier: climate-change-and-human-health
create_dt: 2014-11-25T01:00:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/climate-change-and-human-health/figure/major-us-climate-trends.yaml
identifier: major-us-climate-trends
lat_max: 49.38
lat_min: 24.50
lon_max: -66.95
lon_min: -124.8
ordinal: 1
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: ~
time_start: ~
title: Major U.S. Climate Trends
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/climate-change-and-human-health/figure/major-us-climate-trends
url: ~
usage_limits: Free to use with credit to the original figure source.
- attributes: ~
caption: 'Time series of 5-year averages of the number of extreme 2-day duration precipitation events, averaged over the United States from 1900 to 2014. The number is expressed as the percent difference from the average for the entire period. This is based on 726 stations that have precipitation data for at least 90% of the days in the period. An event is considered extreme if the precipitation amount exceeds a threshold for a once-per-year recurrence. (Figure source: adapted from Mellilo et al. 2014)dd5b893d-4462-4bb3-9205-67b532919566'
chapter_identifier: climate-change-and-human-health
create_dt: 2014-10-29T08:35:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/climate-change-and-human-health/figure/change-in-number-of-extreme-precipitation-events.yaml
identifier: change-in-number-of-extreme-precipitation-events
lat_max: 49.38
lat_min: 24.50
lon_max: -66.95
lon_min: -124.80
ordinal: 2
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: 2014-12-31T23:59:59
time_start: 1900-01-01T00:00:00
title: Change in Number of Extreme Precipitation Events
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/climate-change-and-human-health/figure/change-in-number-of-extreme-precipitation-events
url: ~
usage_limits: Copyright protected. Obtain permission from the original figure source.
- attributes: ~
caption: 'Projected changes in annual average temperature (top) and precipitation (bottom) for 2021–2050 (left) and 2041–2070 (right) with respect to the average for 1971–2000 for the RCP6.0 scenario. The RCP6.0 pathway projects an average global temperature increase of 5.2°F in 2100 over the 1901–1960 global average temperature (the RCPs are described in more detail in Appendix 1: Technical Support Document). Temperature increases in the United States for this scenario (top panels) are in the 2°F to 3°F range for 2021 to 2050 and 2°F to 4°F for 2041 to 2070. This means that the increase in temperature projected in the United States over the next 50 years under this scenario would be larger than the 1°F to 2°F increase in temperature that has already been observed over the previous century. Precipitation is projected to decrease in the Southwest and increase in the Northeast (bottom panels). These projected changes are statistically significant (95% confidence) in small portions of the Northeast, as indicated by the hatching. (Figure source: adapted from Sun et al. 2015)b63c9720-f770-4718-89cc-53b3616e2bec'
chapter_identifier: climate-change-and-human-health
create_dt: 2014-07-21T12:51:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/climate-change-and-human-health/figure/projected-changes-in-temperature-and-precipitation-by-mid-century.yaml
identifier: projected-changes-in-temperature-and-precipitation-by-mid-century
lat_max: 49.38
lat_min: 24.50
lon_max: -66.95
lon_min: -124.80
ordinal: 3
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: 2070-12-31T23:59:59
time_start: 2021-01-01T00:00:00
title: Projected Changes in Temperature and Precipitation by Mid-Century
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/climate-change-and-human-health/figure/projected-changes-in-temperature-and-precipitation-by-mid-century
url: ~
usage_limits: Copyright protected. Obtain permission from the original figure source.
- attributes: ~
caption: 'Projected changes in several climate variables for 2046–2065 with respect to the 1981–2000 average for the RCP6.0 scenario. These include the coldest night of the year (top left) and the hottest day of the year (top right). By the middle of this century, the coldest night of the year is projected to warm by 6°F to 10°F over most of the country, with slightly smaller changes in the south. The warmest day of the year is projected to be 4°F to 6°F warmer in most areas. Also shown above are projections of the wettest day of the year (bottom left) and the annual longest consecutive dry day spell (bottom right). Extreme precipitation is projected to increase, with an average change of 5% to 15% in the precipitation falling on the wettest day of the year. The length of the annual longest dry spell is projected to increase in most areas, but these changes are small: less than two days in most areas. (Figure source: adapted from Sun et al. 2015)b63c9720-f770-4718-89cc-53b3616e2bec'
chapter_identifier: climate-change-and-human-health
create_dt: 2014-07-21T12:51:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/climate-change-and-human-health/figure/projected-changes-in-hottest-coldest-and-wettest-driest-day-of-the-year.yaml
identifier: projected-changes-in-hottest-coldest-and-wettest-driest-day-of-the-year
lat_max: 49.38
lat_min: 24.50
lon_max: -66.95
lon_min: -124.80
ordinal: 4
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: 2065-12-31T23:59:59
time_start: 1981-01-01T00:00:00
title: Projected Changes in Hottest/Coldest and Wettest/Driest Day of the Year
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/climate-change-and-human-health/figure/projected-changes-in-hottest-coldest-and-wettest-driest-day-of-the-year
url: ~
usage_limits: Copyright protected. Obtain permission from the original figure source.
- attributes: ~
caption: 'Conceptual diagram illustrating the exposure pathways by which climate change affects human health. Exposure pathways exist within the context of other factors that positively or negatively influence health outcomes (gray side boxes). Key factors that influence vulnerability for individuals are shown in the right box, and include social determinants of health and behavioral choices. Key factors that influence vulnerability at larger scales, such as natural and built environments, governance and management, and institutions, are shown in the left box. All of these influencing factors can affect an individual’s or a community’s vulnerability through changes in exposure, sensitivity, and adaptive capacity and may also be affected by climate change.'
chapter_identifier: climate-change-and-human-health
create_dt: 2014-10-10T10:00:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/climate-change-and-human-health/figure/climate-change-and-health.yaml
identifier: climate-change-and-health
lat_max: ~
lat_min: ~
lon_max: ~
lon_min: ~
ordinal: 5
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: ~
time_start: ~
title: Climate Change and Health
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/climate-change-and-human-health/figure/climate-change-and-health
url: ~
usage_limits: Free to use with credit to the original figure source.
- attributes: ~
caption: Examples of sources of uncertainty in projecting impacts of climate change on human health. The left column illustrates the exposure pathway through which climate change can affect human health. The right column lists examples of key sources of uncertainty surrounding effects of climate change at each stage along the exposure pathway.
chapter_identifier: climate-change-and-human-health
create_dt: 2015-08-24T11:20:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/climate-change-and-human-health/figure/sources-of-uncertainty.yaml
identifier: sources-of-uncertainty
lat_max: ~
lat_min: ~
lon_max: ~
lon_min: ~
ordinal: 6
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: ~
time_start: ~
title: Sources of Uncertainty
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/climate-change-and-human-health/figure/sources-of-uncertainty
url: ~
usage_limits: ~
- attributes: ~
caption: 'This conceptual diagram illustrates the key pathways by which climate change influences human health during an extreme heat event, and potential resulting health outcomes (center boxes). These exposure pathways exist within the context of other factors that positively or negatively influence health outcomes (gray side boxes). Key factors that influence vulnerability for individuals are shown in the right box, and include social determinants of health and behavioral choices. Key factors that influence vulnerability at larger scales, such as natural and built environments, governance and management, and institutions, are shown in the left box. All of these influencing factors can affect an individual’s or a community’s vulnerability through changes in exposure, sensitivity, and adaptive capacity and may also be affected by climate change. See Chapter 1: Introduction for more information.'
chapter_identifier: temperature-related-death-and-illness
create_dt: 2015-03-05T00:00:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/temperature-related-death-and-illness/figure/climate-change-and-health-extreme-heat.yaml
identifier: climate-change-and-health-extreme-heat
lat_max: ~
lat_min: ~
lon_max: ~
lon_min: ~
ordinal: 1
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: ~
time_start: ~
title: Climate Change and Health--Extreme Heat
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/temperature-related-death-and-illness/figure/climate-change-and-health-extreme-heat
url: ~
usage_limits: Free to use with credit to the original figure source.
- attributes: ~
caption: 'This figure shows the relationship between high temperatures and deaths observed during the 1995 Chicago heat wave. The large spike in deaths in mid-July of 1995 (red line) is much higher than the average number of deaths during that time of year (orange line), as well as the death rate before and after the heat wave. This increase in the rate of deaths occurred during and after the heat wave, as shown here by temperatures exceeding 100°F during the day (green line). Humidity and high nighttime temperatures were also key contributing factors to this increase in deaths.4f9edf45-db7c-4e87-b1ab-af8856388760 The number of excess deaths has been estimated to be about 700 based on statistical methods, but only 465 deaths in Cook County were classified as “heat-related” on death certificates during this same period,e4b23502-00d8-4f34-8da8-3bb61ece107d demonstrating the tendency of direct attribution to undercount total heat-related deaths. (Figure source: EPA 2014)bfc00315-ccea-4e7c-8a05-2650a07e4252'
chapter_identifier: temperature-related-death-and-illness
create_dt: 2014-05-01T12:00:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/temperature-related-death-and-illness/figure/heat-related-deaths-during-the-1995-chicago-heat-wave.yaml
identifier: heat-related-deaths-during-the-1995-chicago-heat-wave
lat_max: 42.2
lat_min: 41.5
lon_max: 88.3
lon_min: 87.1
ordinal: 2
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: 1995-08-30T23:59:59
time_start: 1995-06-01T00:00:00
title: Heat-Related Deaths During the 1995 Chicago Heat Wave
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/temperature-related-death-and-illness/figure/heat-related-deaths-during-the-1995-chicago-heat-wave
url: ~
usage_limits: ~
- attributes: ~
caption: 'This figure shows the projected decrease in death rates due to warming in colder months (October–March, top left), the projected increase in death rates due to warming in the warmer months (April–September, top right), and the projected net change in death rates (combined map, bottom), comparing results for 2100 to those for a 1990 baseline period in 209 U.S. cities. These results are from one of the two climate models (GFDL–CM3 scenario RCP6.0) studied in Schwartz et al. (2015). In the study, mortality data for a city is based on county-level records, so the borders presented reflect counties corresponding to the study cities. Geographic variation in the death rates are due to a combination of differences in the amount of projected warming and variation in the relationship between deaths and temperatures derived from the historical health and temperature data. These results are based on holding the 2010 population constant in the analyses, with no explicit assumptions or adjustment for potential future adaptation. Therefore, these results reflect only the effect of the anticipated change in climate over time. (Figure source: Schwartz et al. 2015)e805bfdc-c4c2-43a0-b2e5-5a66945c74e4'
chapter_identifier: temperature-related-death-and-illness
create_dt: 2014-10-31T12:00:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/temperature-related-death-and-illness/figure/projected-changes-in-temperature-related-death-rates.yaml
identifier: projected-changes-in-temperature-related-death-rates
lat_max: 49.38
lat_min: 24.50
lon_max: -66.95
lon_min: -124.80
ordinal: 3
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: 2100-12-31T23:59:59
time_start: 1975-01-01T00:00:00
title: Projected Changes in Temperature-Related Death Rates
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/temperature-related-death-and-illness/figure/projected-changes-in-temperature-related-death-rates
url: ~
usage_limits: ~
- attributes: ~
caption: 'This figure shows the projected increase in deaths due to warming in the summer months (hot season, April–September), the projected decrease in deaths due to warming in the winter months (cold season, October–March), and the projected net change in deaths for the 209 U.S. cities examined. These results compare projected deaths for future reporting years to results for the year 1990 while holding the population constant at 2010 levels and without any quantitative adjustment for potential future adaptation, so that temperature–death relationships observed in the last decade of the available data (1997–2006) are assumed to remain unchanged in projections over the 21st century. With these assumptions, the figure shows an increasing health benefit in terms of reduced deaths during the cold season (October–March) over the 21st century from warming temperatures, while deaths during the hot season (April–September) increase. Overall, the additional deaths from the warming in the hot season exceed the reduction in deaths during the cold season, resulting in a net increase in deaths attributable to temperature over time as a result of climate change. The baseline and future reporting years are based on 30-year periods where possible, with the exception of 2100: 1990 (1976–2005), 2030 (2016–2045), 2050 (2036–2065), and 2100 (2086–2100). (Figure source: adapted from Schwartz et al. 2015)e805bfdc-c4c2-43a0-b2e5-5a66945c74e4'
chapter_identifier: temperature-related-death-and-illness
create_dt: 2014-10-31T12:00:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/temperature-related-death-and-illness/figure/projected-changes-in-deaths-in-us-cities-by-season.yaml
identifier: projected-changes-in-deaths-in-us-cities-by-season
lat_max: 49.38
lat_min: 24.50
lon_max: -66.95
lon_min: -124.80
ordinal: 4
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: 2100-12-31T23:59:59
time_start: 2030-01-01T00:00:00
title: Projected Changes in Deaths in U.S. Cities by Season
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/temperature-related-death-and-illness/figure/projected-changes-in-deaths-in-us-cities-by-season
url: ~
usage_limits: ~
- attributes: ~
caption: 'This conceptual diagram for an outdoor air quality example illustrates the key pathways by which humans are exposed to health threats from climate drivers, and potential resulting health outcomes (center boxes). These exposure pathways exist within the context of other factors that positively or negatively influence health outcomes (gray side boxes). Key factors that influence vulnerability for individuals are shown in the right box, and include social determinants of health and behavioral choices. Key factors that influence vulnerability at larger scales, such as natural and built environments, governance and management, and institutions, are shown in the left box. All of these influencing factors can affect an individual’s or a community’s vulnerability through changes in exposure, sensitivity, and adaptive capacity and may also be affected by climate change. See Chapter 1: Introduction for more information.'
chapter_identifier: air-quality-impacts
create_dt: 2015-03-05T00:00:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/air-quality-impacts/figure/climate-change-and-health-outdoor-air-quality.yaml
identifier: climate-change-and-health-outdoor-air-quality
lat_max: ~
lat_min: ~
lon_max: ~
lon_min: ~
ordinal: 1
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: ~
time_start: ~
title: Climate Change and Health--Outdoor Air Quality
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/air-quality-impacts/figure/climate-change-and-health-outdoor-air-quality
url: ~
usage_limits: Free to use with credit to the original figure source.
- attributes: ~
caption: 'Projected changes in average daily maximum temperature (degrees Fahrenheit), summer average maximum daily 8-hour ozone (parts per billion), and excess ozone-related deaths (incidences per year by county) in the year 2030 relative to the year 2000, following two global climate models and two greenhouse gas concentration pathways, known as Representative Concentration Pathways, or RCPs (see van Vuuren et al. 201144124472-4a1d-4fbd-b86e-91cca108b938). Each year (2000 and 2030) is represented by 11 years of modeled data for May through September, the traditional ozone season in the United States.
The top panels are based on the National Center for Atmospheric Research/Department of Energy (NCAR/DOE) Community Earth System Model (CESM) following RCP8.5 (a higher greenhouse gas concentration pathway), and the bottom panels are based on the National Aeronautics and Space Administration (NASA) Goddard Institute for Space Studies (GISS) ModelE2-R following RCP6.0 (a moderate greenhouse gas concentration pathway).
The leftmost panels are based on dynamically downscaled regional climate using the NCAR Weather Research and Forecasting (WRF) model, the center panels are based on air quality simulations from the U.S. Environmental Protection Agency (EPA) Community Multiscale Air Quality (CMAQ) model, and the rightmost panels are based on the U.S. EPA Environmental Benefits and Mapping Program (BenMAP).
Fann et al. 2015 reports a range of mortality outcomes based on different methods of computing the mortality effects of ozone changes—the changes in the number of deaths shown in the rightmost panels were computed using the method described in Bell et al. 2004.54a66159-1675-43bb-b5d3-a9b7f283e4de,a02f25a1-29c1-4564-9b41-7d974e8ce6b5 (Figure source: adapted from Fann et al. 2015)54a66159-1675-43bb-b5d3-a9b7f283e4de'
chapter_identifier: air-quality-impacts
create_dt: 2014-10-31T12:34:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/air-quality-impacts/figure/projected-change-in-temperature-ozone-and-ozone-related-premature-deaths-in-2030.yaml
identifier: projected-change-in-temperature-ozone-and-ozone-related-premature-deaths-in-2030
lat_max: 49.38
lat_min: 24.50
lon_max: -66.95
lon_min: -124.80
ordinal: 2
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: 2030-12-31T23:59:59
time_start: 2030-01-01T00:00:00
title: 'Projected Change in Temperature, Ozone, and Ozone-Related Premature Deaths in 2030'
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/air-quality-impacts/figure/projected-change-in-temperature-ozone-and-ozone-related-premature-deaths-in-2030
url: ~
usage_limits: Copyright protected. Obtain permission from the original figure source.
- attributes: ~
caption: 'Projected change in ozone-related premature deaths from 2000 to 2030 by U.S. region and based on CESM/RCP8.5. Each year (2000 and 2030) is represented by 11 years of modeled data. Ozone-related premature deaths were calculated using the risk coefficient from Bell et al. (2004).a02f25a1-29c1-4564-9b41-7d974e8ce6b5 Boxes indicate 25th, 50th, and 75th percentile change over 11-year sample periods, and vertical lines extend to 1.5 times the interquartile range. U.S. regions follow geopolitical boundaries shown in Figure 3.2. (Figure source: Fann et al. 2015)54a66159-1675-43bb-b5d3-a9b7f283e4de'
chapter_identifier: air-quality-impacts
create_dt: 2014-11-07T12:30:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/air-quality-impacts/figure/projected-change-in-ozone-related-premature-deaths.yaml
identifier: projected-change-in-ozone-related-premature-deaths
lat_max: 49.38
lat_min: 24.50
lon_max: -66.95
lon_min: -124.80
ordinal: 3
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: 2035-12-31T23:59:59
time_start: 2025-01-01T00:00:00
title: Projected Change in Ozone-related Premature Deaths
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/air-quality-impacts/figure/projected-change-in-ozone-related-premature-deaths
url: ~
usage_limits: Copyright protected. Obtain permission from the original figure source.
- attributes: ~
caption: 'Ragweed pollen season length has increased in central North America between 1995 and 2011 by as much as 11 to 27 days in parts of the United States and Canada, in response to rising temperatures. Increases in the length of this allergenic pollen season are correlated with increases in the number of days before the first frost. The largest increases have been observed in northern cities. (Figure source: Melillo et al. 2014. Photo credit: Lewis Ziska, USDA).dd5b893d-4462-4bb3-9205-67b532919566'
chapter_identifier: air-quality-impacts
create_dt: 2014-05-01T12:00:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/air-quality-impacts/figure/ragweed-pollen-season-lengthens.yaml
identifier: ragweed-pollen-season-lengthens
lat_max: 52
lat_min: 30
lon_max: 106
lon_min: 89
ordinal: 4
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: 2011-12-31T23:59:59
time_start: 1995-01-01T00:00:00
title: Ragweed Pollen Season Lengthens
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/air-quality-impacts/figure/ragweed-pollen-season-lengthens
url: ~
usage_limits: Copyright protected. Obtain permission from the original figure source.
- attributes: ~
caption: 'This figure provides 10-year estimates of fatalities related to extreme events from 2004 to 2013,a1b08f2f-e94c-4628-b82a-a646e71116ec as well as estimated economic damages from 58 weather and climate disaster events with losses exceeding $1 billion (see Smith and Katz 2013 to understand how total losses were calculated).4fe32146-a968-4dde-8a2b-df2aa2eabdd4 These statistics are indicative of the human and economic costs of extreme weather events over this time period. Climate change will alter the frequency, intensity, and geographic distribution of some of these extremes,dd5b893d-4462-4bb3-9205-67b532919566 which has consequences for exposure to health risks from extreme events. Trends and future projections for some extremes, including tornadoes, lightning, and wind storms are still uncertain.'
chapter_identifier: extreme-events
create_dt: 2015-02-23T00:00:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/extreme-events/figure/estimated-deaths-and-billion-dollar-losses-from-extreme-weather-events-in-the-us-2004-2013.yaml
identifier: estimated-deaths-and-billion-dollar-losses-from-extreme-weather-events-in-the-us-2004-2013
lat_max: 49.28
lat_min: 24.50
lon_max: -66.95
lon_min: -124.80
ordinal: 1
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: 2013-12-31T00:00:00
time_start: 2004-01-01T00:00:00
title: Estimated Deaths and Billion Dollar Losses from Extreme Weather Events in the U.S. 2004-2013
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/extreme-events/figure/estimated-deaths-and-billion-dollar-losses-from-extreme-weather-events-in-the-us-2004-2013
url: ~
usage_limits: Free to use with credit to the original figure source.
- attributes: ~
caption: 'This conceptual diagram for a flooding event illustrates the key pathways by which humans are exposed to health threats from climate drivers, and potential resulting health outcomes (center boxes). These exposure pathways exist within the context of other factors that positively or negatively influence health outcomes (gray side boxes). Key factors that influence health outcomes and vulnerability for individuals are shown in the right box, and include social determinants of health and behavioral choices. Key factors that influence health outcomes and vulnerability at larger community or societal scales, such as natural and built environments, governance and management, and institutions, are shown in the left box. All of these influencing factors may also be affected by climate change. See Chapter 1: Introduction for more information.'
chapter_identifier: extreme-events
create_dt: 2015-03-05T00:00:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/extreme-events/figure/climate-change-and-health-flooding.yaml
identifier: climate-change-and-health-flooding
lat_max: N/A
lat_min: N/A
lon_max: N/A
lon_min: N/A
ordinal: 2
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: ~
time_start: ~
title: Climate Change and Health--Flooding
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/extreme-events/figure/climate-change-and-health-flooding
url: ~
usage_limits: Free to use with credit to the original figure source.
- attributes: ~
caption: 'Composite map of floods associated with landfalling hurricanes over the past 31 years, based on stream gauge data. The Flood Ratio (Q) refers to maximum hurricane-related flood peaks compared to 10-year flood peaks (expected to occur, on average, once every 10 years and corresponds to the 90th percentile of the flood peak distribution) calculated for the same area. See Villarini et al. 2014 for a detailed description of how Q values are calculated.7f29d739-b00c-4140-a922-be8d211ecc5e Q values between 0.6 and 1 (light blue and yellow) generally indicate minor to moderate flooding, while values above 1 (orange and red) generally indicate major flooding larger than the 10-year flood peak. The dark gray areas of the map represent the extent of the 500-km buffer around the center of circulation of the hurricanes included during the study period (the light gray areas of the map fall outside of the study area). Figure 4.3 shows that hurricanes are important contributors to flooding in the eastern United States, as well as large areas of the central United States. Land use/land cover properties and soil moisture conditions are also important factors for flooding. (Figure source: adapted from Villarini et al. 2014)7f29d739-b00c-4140-a922-be8d211ecc5e'
chapter_identifier: extreme-events
create_dt: 2014-01-10T00:00:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/extreme-events/figure/hurricane-induced-flood-effects-in-eastern-and-central-united-states.yaml
identifier: hurricane-induced-flood-effects-in-eastern-and-central-united-states
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ordinal: 3
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: 2011-12-31T23:59:59
time_start: 1981-01-01T00:00:00
title: Hurricane-Induced Flood Effects in Eastern and Central United States
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/extreme-events/figure/hurricane-induced-flood-effects-in-eastern-and-central-united-states
url: ~
usage_limits: Copyright protected. Obtain permission from the original figure source.
- attributes: ~
caption: 'Based on 17 climate model simulations for the continental United States using a higher emissions pathway (RCP8.5), the map shows projected percentage increases in weeks with risk of very large fires by mid-century (2041-2070) compared to the recent past (1971-2000). The darkest shades of red indicated that up to a 6-fold increase in risk is projected for parts of the West. This area includes the Great Basin, Northern Rockies, and parts of Northern California. Gray represents areas within the continental United States where there is either no data or insufficient historical observations on very large fires to build robust models. The potential for very large fire events is also expected to increase along the southern coastline and in areas around the Great Lakes. (Figure source: adapted from Barbero et al. 2015 by NOAA)ca5c4b38-9aa8-4edc-9aea-42f1625cc45b'
chapter_identifier: extreme-events
create_dt: 2015-09-10T09:33:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/extreme-events/figure/projected-increases-in-very-large-fires.yaml
identifier: projected-increases-in-very-large-fires
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ordinal: 4
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: ~
time_start: ~
title: Projected Increases in Very Large Fires
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/extreme-events/figure/projected-increases-in-very-large-fires
url: ~
usage_limits: Copyright protected. Obtain permission from the original figure source.
- attributes: ~
caption: 'This conceptual diagram illustrates the key pathways by which climate change influences human exposure to Lyme disease and the potential resulting health outcomes (center boxes). These exposure pathways exist within the context of other factors that positively or negatively influence health outcomes (gray side boxes). Key factors that influence vulnerability for individuals are shown in the right box, and include social determinants of health and behavioral choices. Key factors that influence vulnerability at larger scales, such as natural and built environments, governance and management, and institutions, are shown in the left box. All of these influencing factors can affect an individual’s or a community’s vulnerability through changes in exposure, sensitivity, and adaptive capacity and may also be affected by climate change. See Ch. 1: Introduction for more information.'
chapter_identifier: vectorborne-diseases
create_dt: 2015-03-05T00:00:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/vectorborne-diseases/figure/climate-change-and-health-lyme-disease.yaml
identifier: climate-change-and-health-lyme-disease
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lon_max: N/A
lon_min: N/A
ordinal: 1
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: ~
time_start: ~
title: Climate Change and Health--Lyme Disease
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/vectorborne-diseases/figure/climate-change-and-health-lyme-disease
url: ~
usage_limits: Free to use with credit to the original figure source.
- attributes: ~
caption: 'Maps show the reported cases of Lyme disease in 2001 and 2014 for the areas of the country where Lyme disease is most common (the Northeast and Upper Midwest). Both the distribution and the numbers of cases have increased. (Figure source: adapted from CDC 2015)6066212c-7cfd-46af-8255-e6c75647167a'
chapter_identifier: vectorborne-diseases
create_dt: 2015-10-01T12:00:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/vectorborne-diseases/figure/changes-in-lyme-disease-case-report-distribution.yaml
identifier: changes-in-lyme-disease-case-report-distribution
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lon_max: 48.0
lon_min: 36.0
ordinal: 2
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: 2014-12-31T23:59:59
time_start: 2001-01-01T00:00:00
title: Changes in Lyme Disease Case Report Distribution
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/vectorborne-diseases/figure/changes-in-lyme-disease-case-report-distribution
url: ~
usage_limits: ~
- attributes: ~
caption: 'Figure depicts the life cycle of blacklegged ticks, including the phases in which humans can be exposed to Lyme disease, and some of the changes in seasonality expected with climate change. (Figure source: adapted from CDC 2015)f4eeeade-8af7-4d4a-9a9c-af712338b208'
chapter_identifier: vectorborne-diseases
create_dt: 2010-09-09T12:00:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/vectorborne-diseases/figure/life-cycle-of-blacklegged-ticks-ixodes-scapularis.yaml
identifier: life-cycle-of-blacklegged-ticks-ixodes-scapularis
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lat_min: ~
lon_max: ~
lon_min: ~
ordinal: 3
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: ~
time_start: ~
title: 'Life Cycle of Blacklegged Ticks, Ixodes scapularis'
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/vectorborne-diseases/figure/life-cycle-of-blacklegged-ticks-ixodes-scapularis
url: ~
usage_limits: ~
- attributes: ~
caption: 'Box plots comparing the distributions of the national-level historical observed data for annual Lyme onset week (1992–2007 in green) with the distributions of AOGCM multi-model mean projections of Lyme onset week for each of four Representative Concentration Pathways (RCP2.6, 4.5, 6.0, and 8.5) and two future time periods (2025–2040 in blue, 2065–2080 in red). Each box plot shows the values of Lyme disease onset week for the maximum (top of dashed line), 75th percentile (top of box), average (line through box), 25th percentile (bottom of box), and minimum (bottom of dashed line) of the distribution. All distributions are comprised of values for 12 eastern states and 16 years (N = 192). Additional details can be found in Monaghan et al. (2015). (Figure source: adapted from Monaghan et al. 2015).953d1436-e0d0-426c-8dcc-68e5c02eef30'
chapter_identifier: vectorborne-diseases
create_dt: 2014-10-30T12:00:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/vectorborne-diseases/figure/projected-change-in-lyme-disease-onset-week.yaml
identifier: projected-change-in-lyme-disease-onset-week
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ordinal: 4
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: 2080-12-31T23:59:59
time_start: 1992-01-01T00:00:00
title: Projected Change in Lyme Disease Onset Week
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/vectorborne-diseases/figure/projected-change-in-lyme-disease-onset-week
url: ~
usage_limits: Copyright protected. Obtain permission from the original figure source.
- attributes: ~
caption: 'Maps show the incidence of West Nile neuroinvasive disease in the United States for 2010 through 2013. Shown as cases per 100,000 people. (Data source: CDC 2014)2eb0f9eb-b977-49c5-88b6-a1e513414225'
chapter_identifier: vectorborne-diseases
create_dt: 2014-11-17T00:00:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/vectorborne-diseases/figure/incidence-of-west-nile-neuroinvasive-disease-by-county-in-the-united-states.yaml
identifier: incidence-of-west-nile-neuroinvasive-disease-by-county-in-the-united-states
lat_max: 49.38
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lon_max: -66.95
lon_min: -124.80
ordinal: 5
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: 2013-12-31T23:59:59
time_start: 2010-01-01T00:00:00
title: Incidence of West Nile Neuroinvasive Disease by County in the United States
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/vectorborne-diseases/figure/incidence-of-west-nile-neuroinvasive-disease-by-county-in-the-united-states
url: ~
usage_limits: Free to use with credit to the original figure source.
- attributes: ~
caption: ~
chapter_identifier: vectorborne-diseases
create_dt: 2014-12-03T00:00:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/vectorborne-diseases/figure/climate-impacts-on-west-nile-virus-transmission.yaml
identifier: climate-impacts-on-west-nile-virus-transmission
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lon_min: N/A
ordinal: 6
report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: ~
time_start: ~
title: Climate Impacts on West Nile Virus Transmission
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/vectorborne-diseases/figure/climate-impacts-on-west-nile-virus-transmission
url: ~
usage_limits: Copyright protected. Obtain permission from the original figure source.
- attributes: ~
caption: 'This conceptual diagram for an example of infection by Vibrio species (V. vulnificus, V. parahaemolyticus, or V. alginolyticus) illustrates the key pathways by which humans are exposed to health threats from climate drivers. These climate drivers create more favorable growing conditions for these naturally occurring pathogens in coastal environments through their effects on coastal salinity, turbidity (water clarity), or plankton abundance and composition. Longer seasons for growth and expanding geographic range of occurrence increase the risk of exposure to Vibrio, which can result in various potential health outcomes (center boxes). These exposure pathways exist within the context of other factors that positively or negatively influence health outcomes (gray side boxes). Key factors that influence vulnerability for individuals are shown in the right box and include social determinants of health and behavioral choices. Key factors that influence vulnerability at larger scales, such as natural and built environments, governance and management, and institutions, are shown in the left box. All of these influencing factors can affect an individual’s or a community’s vulnerability through changes in exposure, sensitivity, and adaptive capacity and may also be affected by climate change. See Ch. 1: Introduction for more information.'
chapter_identifier: water-related-illnesses
create_dt: 2015-03-16T00:00:00
href: https://data.globalchange.gov/report/usgcrp-climate-human-health-assessment-2016/chapter/water-related-illnesses/figure/climate-change-and-health-vibrio.yaml
identifier: climate-change-and-health-vibrio
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report_identifier: usgcrp-climate-human-health-assessment-2016
source_citation: ~
submission_dt: ~
time_end: ~
time_start: ~
title: 'Climate Change and Health - Vibrio'
uri: /report/usgcrp-climate-human-health-assessment-2016/chapter/water-related-illnesses/figure/climate-change-and-health-vibrio
url: ~
usage_limits: Free to use with credit to the original figure source.