---
- attributes: ~
  caption: "Sea level rise presents major challenges to South Florida’s existing coastal water management system due\r\n    to a combination of increasingly urbanized areas, aging flood control facilities, flat topography, and porous limestone\r\n    aquifers. For instance, South Florida’s freshwater well field protection areas (left map: pink areas) lie\r\n    close to the current interface between saltwater and freshwater (red line), which will shift inland with rising sea\r\n    level, affectingwater managers’ ability to draw drinking water from current\r\n    resources. Coastal water control structures (right map: yellow circles) that were originally built about 60 years ago at\r\n    the ends of drainage canals to keep saltwater out and to provide flood protection to urbanized areas along the coast are now\r\n    threatened by sea level rise. Even today, residents in some areas such as Miami Beach are experiencing seawater flooding their\r\n    streets (lower photo). (Maps from The South Florida Water Management\r\n    District.<tbib>0a764a80-1238-4980-a5e3-bdd348124cc4</tbib> Photo credit: Luis Espinoza,\r\n    Miami-Dade County Department of Regulatory and Economic Resources)."
  chapter_identifier: southeast
  create_dt: ~
  href: http://52.38.26.42:8080/report/nca3/chapter/southeast/figure/south-florida-uniquely-vulnerable-to-sea-level-rise.yaml
  identifier: south-florida-uniquely-vulnerable-to-sea-level-rise
  lat_max: ~
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  ordinal: 8
  report_identifier: nca3
  source_citation: ~
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: 'South Florida: Uniquely Vulnerable to Sea Level Rise'
  uri: /report/nca3/chapter/southeast/figure/south-florida-uniquely-vulnerable-to-sea-level-rise
  url: http://nca2014.globalchange.gov/report/regions/southeast/graphics/south-florida-uniquely-vulnerable-sea-level-rise
  usage_limits: Free to use with credit to the original figure source.
- attributes: ~
  caption: "Miami-Dade County staff leading workshop on incorporating climate change considerations in local planning.\r\n    (Photo credit: Armando Rodriguez, Miami-Dade County)."
  chapter_identifier: southeast
  create_dt: 2013-11-18T16:00:59
  href: http://52.38.26.42:8080/report/nca3/chapter/southeast/figure/local-planning.yaml
  identifier: local-planning
  lat_max: ~
  lat_min: ~
  lon_max: ~
  lon_min: ~
  ordinal: 9
  report_identifier: nca3
  source_citation: ~
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: Local Planning
  uri: /report/nca3/chapter/southeast/figure/local-planning
  url: http://nca2014.globalchange.gov/report/regions/southeast/graphics/local-planning
  usage_limits: Copyright protected. Obtain permission from the original figure source.
- attributes: ~
  caption: "Ground-level ozone is an air pollutant that is harmful to human health and which\r\n    generally increases with rising temperatures. The map shows projected\r\n    changes in average annualground level\r\n    ozone pollution concentration in 2050 as compared to 2001, using a mid-range emissions scenario (A1B, which assumes gradual\r\n    reductions from current emissions trends beginning around mid-century). (Figure source: adapted from Tagaris et al.\r\n    2009<tbib>c275ae44-75e4-4974-81ea-fe7119474ffb</tbib>)."
  chapter_identifier: southeast
  create_dt: 2014-02-21T11:01:01
  href: http://52.38.26.42:8080/report/nca3/chapter/southeast/figure/groundlevel-ozone.yaml
  identifier: groundlevel-ozone
  lat_max: ~
  lat_min: ~
  lon_max: ~
  lon_min: ~
  ordinal: 10
  report_identifier: nca3
  source_citation: 'adapted from Tagaris et al. 2009<tbib>c275ae44-75e4-4974-81ea-fe7119474ffb</tbib>'
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: Ground-level Ozone
  uri: /report/nca3/chapter/southeast/figure/groundlevel-ozone
  url: http://nca2014.globalchange.gov/report/regions/southeast/graphics/ground-level-ozone
  usage_limits: Copyright protected. Obtain permission from the original figure source.
- attributes: ~
  caption: "Left: Projected trend in Southeast-wide annual water yield (equivalent to water availability) due to climate\r\n    change. The green area represents the range in predicted water yield from four climate model projections based on the A1B and\r\n    B2 emissions scenarios. Right: Spatial pattern of change in water yield for 2010-2060 (decadal trend relative to 2010).\r\n    The hatched areas are those where the predicted negative trend in water\r\n    availability associated with the range of climate scenarios is statistically significant (with 95% confidence).\r\n    As shown on the map, the western part of the Southeast region is expected to see the largest reductions in water\r\n    availability. (Figure source: adapted from Sun et al. 2013<tbib>ea3445e7-7601-48c1-9a36-bbd7befc0964</tbib>)."
  chapter_identifier: southeast
  create_dt: 2013-11-18T16:23:00
  href: http://52.38.26.42:8080/report/nca3/chapter/southeast/figure/trends-in-water-availability.yaml
  identifier: trends-in-water-availability
  lat_max: ~
  lat_min: ~
  lon_max: ~
  lon_min: ~
  ordinal: 11
  report_identifier: nca3
  source_citation: 'adapted from Sun et al. 2013 <tbib>ea3445e7-7601-48c1-9a36-bbd7befc0964</tbib>'
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: Trends in Water Availability
  uri: /report/nca3/chapter/southeast/figure/trends-in-water-availability
  url: http://nca2014.globalchange.gov/report/regions/southeast/graphics/trends-water-availability
  usage_limits: Copyright protected. Obtain permission from the original figure source.
- attributes: ~
  caption: "The Apalachicola-Chattahoochee-Flint River Basin in Georgia exemplifies a place where many water uses are in\r\n    conflict, and future climate change is expected to exacerbate this\r\n    conflict.<tbib>47f6b2ff-a48f-4b48-899d-a901424bf5b2</tbib> The basin drains 19,600 square miles in\r\n    three states and supplies water for multiple, often competing, uses, including irrigation, drinking water and other municipal\r\n    uses, power plant cooling, navigation, hydropower, recreation, and ecosystems. Under future climate change, this basin is\r\n    likely to experience more severe water supply shortages, more frequent emptying of reservoirs, violation of environmental flow\r\n    requirements (with possible impacts to fisheries at the mouth of the Apalachicola), less energy\r\n    generation, and more competition for remaining water. Adaptation options include changes in reservoir storage and release\r\n    procedures and possible phased expansion of reservoir\r\n    capacity.<tbib>47f6b2ff-a48f-4b48-899d-a901424bf5b2</tbib><sup>,</sup><tbib>7259bc2b-d0aa-460b-b37a-79a11a386e00</tbib><sup>,</sup><tbib>412047fe-33cf-49b8-b714-f1a7b096cd43</tbib>\r\n    Additional adaptation options could include water conservation and demand management. (Figure source:\r\n    Georgakakos et al. 2010<tbib>47f6b2ff-a48f-4b48-899d-a901424bf5b2</tbib>)."
  chapter_identifier: southeast
  create_dt: 2013-11-18T16:25:00
  href: http://52.38.26.42:8080/report/nca3/chapter/southeast/figure/a-southeast-river-basin-under-stress.yaml
  identifier: a-southeast-river-basin-under-stress
  lat_max: ~
  lat_min: ~
  lon_max: ~
  lon_min: ~
  ordinal: 12
  report_identifier: nca3
  source_citation: 'Georgakakos et al. 2010<tbib>47f6b2ff-a48f-4b48-899d-a901424bf5b2</tbib>'
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: A Southeast River Basin Under Stress
  uri: /report/nca3/chapter/southeast/figure/a-southeast-river-basin-under-stress
  url: http://nca2014.globalchange.gov/report/regions/southeast/graphics/southeast-river-basin-under-stress
  usage_limits: Copyright protected. Obtain permission from the original figure source.
- attributes: ~
  caption: 'Annual average temperatures (red line) across the Midwest show a trend towards increasing temperature. The trend (heavy black line) calculated over the period 1895-2012 is equal to an increase of 1.5°F. (Figure source: updated from Kunkel et al. 2013<tbib>95f2ea7d-12e3-4ed5-9247-7cf139db91a9</tbib>).'
  chapter_identifier: midwest
  create_dt: 2013-06-28T11:36:15
  href: http://52.38.26.42:8080/report/nca3/chapter/midwest/figure/temperatures-are-rising-in-the-midwest.yaml
  identifier: temperatures-are-rising-in-the-midwest
  lat_max: ~
  lat_min: ~
  lon_max: ~
  lon_min: ~
  ordinal: 1
  report_identifier: nca3
  source_citation: 'updated from Kunkel et al. 2013<tbib>95f2ea7d-12e3-4ed5-9247-7cf139db91a9</tbib>'
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: Temperatures are Rising in the Midwest
  uri: /report/nca3/chapter/midwest/figure/temperatures-are-rising-in-the-midwest
  url: http://nca2014.globalchange.gov/report/regions/midwest/graphics/temperatures-are-rising-midwest
  usage_limits: Free to use with credit to the original figure source.
- attributes: ~
  caption: 'Projected increase in annual average temperatures by mid-century (2041-2070) as compared to the 1971-2000 period tell only part of the climate change story. Maps also show annual projected increases in the number of the hottest days (days over 95°F), longer frost-free seasons, and an increase in cooling degree days, defined as the number of degrees that a day’s average temperature is above 65°F, which generally leads to an increase in energy use for air conditioning. Projections are from global climate models that assume emissions of heat-trapping gases continue to rise (A2 scenario). (Figure source: NOAA NCDC / CICS-NC).'
  chapter_identifier: midwest
  create_dt: 2013-11-19T16:16:52
  href: http://52.38.26.42:8080/report/nca3/chapter/midwest/figure/projected-midcentury-temperature-changes-in-the-midwest.yaml
  identifier: projected-midcentury-temperature-changes-in-the-midwest
  lat_max: ~
  lat_min: ~
  lon_max: ~
  lon_min: ~
  ordinal: 2
  report_identifier: nca3
  source_citation: NOAA NCDC / CICS-NC
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: Projected Mid-Century Temperature Changes in the Midwest
  uri: /report/nca3/chapter/midwest/figure/projected-midcentury-temperature-changes-in-the-midwest
  url: http://nca2014.globalchange.gov/highlights/regions/midwest/graphics/projected-climate-change
  usage_limits: Free to use with credit to the original figure source.
- attributes: ~
  caption: 'Crop yields are very sensitive to temperature and rainfall. They are especially sensitive to high temperatures during the pollination and grain filling period. For example, corn (left) and soybean (right) harvests in Illinois and Indiana, two major producers, were lower in years with average maximum summer (June, July, and August) temperatures higher than the average from 1980 to 2007. Most years with below-average yields are both warmer and drier than normal.<tbib>9c3f871b-4405-4d6b-bf56-439b678f7025</tbib><sup>,</sup><tbib>3dccc6c2-6a42-49ef-990b-853a220a28f4</tbib> There is high correlation between warm and dry conditions during Midwest summers<tbib>9f976ed6-c1dd-437d-aaf9-062bca25bbc9</tbib> due to similar meteorological conditions and drought-caused changes.<tbib>2ad99c76-b8df-4faa-b52e-095bb4094cab</tbib> (Figure source: Mishra and Cherkauer 2010<tbib>9c3f871b-4405-4d6b-bf56-439b678f7025</tbib>).'
  chapter_identifier: midwest
  create_dt: 2013-11-14T14:43:00
  href: http://52.38.26.42:8080/report/nca3/chapter/midwest/figure/crop-yields-decline-under-higher-temperatures.yaml
  identifier: crop-yields-decline-under-higher-temperatures
  lat_max: ~
  lat_min: ~
  lon_max: ~
  lon_min: ~
  ordinal: 3
  report_identifier: nca3
  source_citation: 'Mishra and Cherkauer 2010<tbib>9c3f871b-4405-4d6b-bf56-439b678f7025</tbib>'
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: Crop Yields Decline under Higher Temperatures
  uri: /report/nca3/chapter/midwest/figure/crop-yields-decline-under-higher-temperatures
  url: http://nca2014.globalchange.gov/highlights/report-findings/agriculture/graphics/crop-yields-decline-under-higher-temperatures
  usage_limits: Copyright protected. Obtain permission from the original figure source.
- attributes: ~
  caption: "As climate changes, species can often adapt by changing their ranges. Maps show current and projected future\r\n    distribution of habitats for forest types in the Midwest under two emissions scenarios, a lower scenario that assumes\r\n    reductions in heat-trapping gas emissions (B1), and a very high scenario that assumes continued increases in emissions (A1FI).\r\n    Habitats for white/red/jack pine, maple/beech/birch, spruce/fir, and aspen/birch forests are projected to greatly decline from\r\n    the northern forests, especially under higher emissions scenarios, while various oak forest types are projected to\r\n    expand.<tbib>fb94e3f2-7687-4d1b-9fdb-b7e2dc8bce84</tbib> While some forest types may not remain\r\n    dominant, they will still be present in reduced quantities. Therefore, it is more appropriate to assess changes on an\r\n    individual species basis, since all species within a forest type will not exhibit equal responses to climate change. (Figure source: Prasad et al. 2007<tbib>fb94e3f2-7687-4d1b-9fdb-b7e2dc8bce84</tbib>)."
  chapter_identifier: midwest
  create_dt: 2013-11-14T14:47:00
  href: http://52.38.26.42:8080/report/nca3/chapter/midwest/figure/forest-composition-shifts.yaml
  identifier: forest-composition-shifts
  lat_max: ~
  lat_min: ~
  lon_max: ~
  lon_min: ~
  ordinal: 4
  report_identifier: nca3
  source_citation: 'Prasad et al. 2007<tbib>fb94e3f2-7687-4d1b-9fdb-b7e2dc8bce84</tbib>'
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: Forest Composition Shifts
  uri: /report/nca3/chapter/midwest/figure/forest-composition-shifts
  url: http://nca2014.globalchange.gov/report/regions/midwest/graphics/forest-composition-shifts
  usage_limits: Free to use with credit to the original figure source.
- attributes: ~
  caption: 'Annual reduction in the number of premature deaths and annual change in the number of cases with acute respiratory symptoms due to reductions in particulate matter and ozone caused by reducing automobile exhaust. The maps project health benefits if automobile trips shorter than five miles (round-trip) were eliminated for the 11 largest metropolitan areas in the Midwest. Making 50% of these trips by bicycle just during four summer months would save 1,295 lives and yield savings of more than $8 billion per year from improved air quality, avoided mortality, and reduced health care costs for the upper Midwest alone. (Figure source: Grabow et al. 2012; reproduced with permission from Environmental Health Perspectives<tbib>4feed3ba-a773-445b-a97d-383477321352</tbib>).'
  chapter_identifier: midwest
  create_dt: 2013-09-10T08:56:00
  href: http://52.38.26.42:8080/report/nca3/chapter/midwest/figure/reducing-emissions-improving-health.yaml
  identifier: reducing-emissions-improving-health
  lat_max: ~
  lat_min: ~
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  lon_min: ~
  ordinal: 5
  report_identifier: nca3
  source_citation: 'Grabow et al. 2012; reproduced with permission from Environmental Health Perspectives<tbib>4feed3ba-a773-445b-a97d-383477321352</tbib>'
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: 'Reducing Emissions, Improving Health'
  uri: /report/nca3/chapter/midwest/figure/reducing-emissions-improving-health
  url: http://nca2014.globalchange.gov/report/regions/midwest/graphics/reducing-emissions-improving-health
  usage_limits: Copyright protected. Obtain permission from the original figure source.
- attributes: ~
  caption: 'Precipitation patterns affect many aspects of life, from agriculture to urban storm drains. These maps show projected changes for the middle of the current century (2041-2070) relative to the end of the last century (1971-2000) across the Midwest under continued emissions (A2 scenario). Top left: the changes in total annual average precipitation. Across the entire Midwest, the total amount of water from rainfall and snowfall is projected to increase. Top right: increase in the number of days with very heavy precipitation (top 2% of all rainfalls each year). Bottom left: increases in the amount of rain falling in the wettest 5-day period over a year. Both (top right and bottom left) indicate that heavy precipitation events will increase in intensity in the future across the Midwest. Bottom right: change in the average maximum number of consecutive days each year with less than 0.01 inches of precipitation. An increase in this variable has been used to indicate an increase in the chance of drought in the future. (Figure source: NOAA NCDC / CICS-NC).'
  chapter_identifier: midwest
  create_dt: 2014-02-05T10:28:18
  href: http://52.38.26.42:8080/report/nca3/chapter/midwest/figure/when-it-rains-it-pours.yaml
  identifier: when-it-rains-it-pours
  lat_max: ~
  lat_min: ~
  lon_max: ~
  lon_min: ~
  ordinal: 6
  report_identifier: nca3
  source_citation: NOAA NCDC / CICS-NC
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: 'When it Rains, it Pours'
  uri: /report/nca3/chapter/midwest/figure/when-it-rains-it-pours
  url: http://nca2014.globalchange.gov/report/regions/midwest/graphics/when-it-rains-it-pours
  usage_limits: Free to use with credit to the original figure source.
- attributes: ~
  caption: 'Bars show decade averages of annual maximum Great Lakes ice coverage from the winter of 1962-1963, when reliable coverage of the entire Great Lakes began, to the winter of 2012-2013. Bar labels indicate the end year of the winter; for example, 1963-1972 indicates the winter of 1962-1963 through the winter of 1971-1972. The most recent period includes the eleven years from 2003 to 2013. (Data updated from Bai and Wang, 2012<tbib>334caaf0-faab-4f7f-8086-c1b216a3b371</tbib>).'
  chapter_identifier: midwest
  create_dt: 2013-11-01T09:16:00
  href: http://52.38.26.42:8080/report/nca3/chapter/midwest/figure/midwest-ice-cover-in-the-great-lakes.yaml
  identifier: midwest-ice-cover-in-the-great-lakes
  lat_max: ~
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  lon_min: ~
  ordinal: 7
  report_identifier: nca3
  source_citation: ~
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: Ice Cover in the Great Lakes
  uri: /report/nca3/chapter/midwest/figure/midwest-ice-cover-in-the-great-lakes
  url: http://nca2014.globalchange.gov/highlights/regions/midwest/graphics/great-lakes-ice-cover-decline
  usage_limits: Free to use with credit to the original figure source.
- attributes: ~
  caption: 'The region has a distinct north-south gradient in average temperature patterns (left), with a hotter south and colder north. For precipitation (right), the regional gradient runs west-east, with a wetter east and a much drier west. Averages shown here are for the period 1981-2010. (Figure source: adapted from Kunkel et al. 2013<tbib>994416dc-705b-4063-b8f5-bd3ed21d4a71</tbib>).'
  chapter_identifier: great-plains
  create_dt: 2013-11-14T13:24:44
  href: http://52.38.26.42:8080/report/nca3/chapter/great-plains/figure/temperature-and-precipitation-distribution-in-the-great-plains.yaml
  identifier: temperature-and-precipitation-distribution-in-the-great-plains
  lat_max: ~
  lat_min: ~
  lon_max: ~
  lon_min: ~
  ordinal: 1
  report_identifier: nca3
  source_citation: 'adapted from Kunkel et al. 2013<tbib>994416dc-705b-4063-b8f5-bd3ed21d4a71</tbib>'
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: Temperature and Precipitation Distribution in the Great Plains
  uri: /report/nca3/chapter/great-plains/figure/temperature-and-precipitation-distribution-in-the-great-plains
  url: http://nca2014.globalchange.gov/report/regions/great-plains/graphics/temperature-and-precipitation-distribution-great-plains
  usage_limits: Free to use with credit to the original figure source.
- attributes: ~
  caption: 'The number of days with the hottest temperatures is projected to increase dramatically. The historical (1971-2000) distribution of temperature for the hottest 2% of days (about seven days each year) echoes the distinct north-south gradient in average temperatures. However, by mid-century (2041-2070), the projected change in number of days exceeding those hottest temperatures is greatest in the western areas and Gulf Coast for both the lower emissions scenario (B1) and for the higher emissions scenario (A2). (Figure source: NOAA NCDC / CICS-NC).'
  chapter_identifier: great-plains
  create_dt: 2013-11-12T10:40:39
  href: http://52.38.26.42:8080/report/nca3/chapter/great-plains/figure/projected-change-in-number-of-hot-days.yaml
  identifier: projected-change-in-number-of-hot-days
  lat_max: ~
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  lon_max: ~
  lon_min: ~
  ordinal: 2
  report_identifier: nca3
  source_citation: NOAA NCDC / CICS-NC
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: Projected Change in Number of Hot Days
  uri: /report/nca3/chapter/great-plains/figure/projected-change-in-number-of-hot-days
  url: http://nca2014.globalchange.gov/report/regions/great-plains/graphics/projected-change-number-hot-days
  usage_limits: Free to use with credit to the original figure source.
- attributes: ~
  caption: 'The number of nights with the warmest temperatures is projected to increase dramatically. The historical (1971-2000) distribution of temperature for the warmest 2% of nights (Top: about seven days each year) echoes the distinct north-south gradient in average temperatures. By mid-century (2041-2070), the projected change in number of nights exceeding those warmest temperatures is greatest in the south for both the lower emissions scenario (B1) and for the higher emissions scenario (A2). (Figure source: NOAA NCDC / CICS-NC).'
  chapter_identifier: great-plains
  create_dt: 2013-11-12T10:43:08
  href: http://52.38.26.42:8080/report/nca3/chapter/great-plains/figure/projected-change-in-number-of-warm-nights.yaml
  identifier: projected-change-in-number-of-warm-nights
  lat_max: ~
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  lon_max: ~
  lon_min: ~
  ordinal: 3
  report_identifier: nca3
  source_citation: NOAA NCDC / CICS-NC
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: Projected Change in Number of Warm Nights
  uri: /report/nca3/chapter/great-plains/figure/projected-change-in-number-of-warm-nights
  url: http://nca2014.globalchange.gov/report/regions/great-plains/graphics/projected-change-number-warm-nights
  usage_limits: Free to use with credit to the original figure source.
- attributes: ~
  caption: 'The number of days with the heaviest precipitation is not projected to change dramatically. The historical (1971-2000) distribution of the greatest 2% of daily precipitation (Top: about seven days each year) echoes the regional east-west gradient in average precipitation. By mid-century (2041-2070), the projected change in days exceeding those precipitation amounts remains greatest in the northern area for both the lower emissions scenario (B1) and for the higher emissions scenario (A2). (Figure source: NOAA NCDC / CICS-NC).'
  chapter_identifier: great-plains
  create_dt: 2013-11-12T10:46:39
  href: http://52.38.26.42:8080/report/nca3/chapter/great-plains/figure/projected-change-in-number-of-heavy-precipitation-days.yaml
  identifier: projected-change-in-number-of-heavy-precipitation-days
  lat_max: ~
  lat_min: ~
  lon_max: ~
  lon_min: ~
  ordinal: 4
  report_identifier: nca3
  source_citation: NOAA NCDC / CICS-NC
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: Projected Change in Number of Heavy Precipitation Days
  uri: /report/nca3/chapter/great-plains/figure/projected-change-in-number-of-heavy-precipitation-days
  url: http://nca2014.globalchange.gov/report/regions/great-plains/graphics/projected-change-number-heavy-precipitation-days
  usage_limits: Free to use with credit to the original figure source.
- attributes: ~
  caption: 'Current regional trends of a drier south and a wetter north are projected to become more pronounced by mid-century (2041-2070 as compared to 1971-2000 averages). Maps show the maximum annual number of consecutive days in which limited (less than 0.01 inches) precipitation was recorded on average from 1971 to 2000 (top), projected changes in the number of consecutive dry days assuming substantial reductions in emissions (B1), and projected changes if emissions continue to rise (A2). The southeastern Great Plains, which is the wettest portion of the region, is projected to experience large increases in the number of consecutive dry days. (Figure source: NOAA NCDC / CICS-NC).'
  chapter_identifier: great-plains
  create_dt: 2013-11-18T14:28:37
  href: http://52.38.26.42:8080/report/nca3/chapter/great-plains/figure/projected-change-in-number-of-consecutive-dry-days.yaml
  identifier: projected-change-in-number-of-consecutive-dry-days
  lat_max: ~
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  lon_min: ~
  ordinal: 5
  report_identifier: nca3
  source_citation: NOAA NCDC / CICS-NC
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: Projected Change in Number of Consecutive Dry Days
  uri: /report/nca3/chapter/great-plains/figure/projected-change-in-number-of-consecutive-dry-days
  url: http://nca2014.globalchange.gov/report/regions/great-plains/graphics/projected-change-number-consecutive-dry-days
  usage_limits: Free to use with credit to the original figure source.
- attributes: ~
  caption: 'Irrigation in western Kansas, Oklahoma, and Texas supports crop development in semiarid areas. Declining aquifer levels threaten the ability to maintain production. Some aquifer-dependent regions, like southeastern Nebraska, have seen steep rises in irrigated farmland, from around 5% to more than 40%, during the period shown. (Figure source: reproduced from Atlas of the Great Plains by Stephen J. Lavin, Clark J. Archer, and Fred M. Shelley by permission of the University of Nebraska. Copyright 2011 by the Board of Regents of the University of Nebraska<tbib>78ea39e1-a79d-4219-aa6c-7681d3dde246</tbib>).'
  chapter_identifier: great-plains
  create_dt: 2013-11-14T13:32:00
  href: http://52.38.26.42:8080/report/nca3/chapter/great-plains/figure/increases-in-irrigated-farmland-in-the-great-plains.yaml
  identifier: increases-in-irrigated-farmland-in-the-great-plains
  lat_max: ~
  lat_min: ~
  lon_max: ~
  lon_min: ~
  ordinal: 6
  report_identifier: nca3
  source_citation: 'reproduced from Atlas of the Great Plains by Stephen J. Lavin, Clark J. Archer, and Fred M. Shelley by permission of the University of Nebraska. Copyright 2011 by the Board of Regents of the University of Nebraska<tbib>78ea39e1-a79d-4219-aa6c-7681d3dde246</tbib>'
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: Increases in Irrigated Farmland in the Great Plains
  uri: /report/nca3/chapter/great-plains/figure/increases-in-irrigated-farmland-in-the-great-plains
  url: http://nca2014.globalchange.gov/report/regions/great-plains/graphics/increases-irrigated-farmland-great-plains
  usage_limits: Copyright protected. Obtain permission from the original figure source.
- attributes: ~
  caption: "Comparing estimates of Greater Sage Grouse distribution from before settlement of the area (light green: prior\r\n    to about 1800) with the current range (dark green: 2000) shows fragmentation of the sagebrush habitat required by this species.\r\n    Over the last century, the sagebrush ecosystem has been altered by fire, invasion by new plant species, and conversion of land\r\n    to agriculture, causing a decline in Sage Grouse populations. (Figure source: adapted from Aldridge et al.\r\n    2008.<tbib>7c7085fc-ad53-4b51-8fa1-8856ae91c411</tbib> Photo credit: U.S. Fish and Wildlife Service,\r\n    Wyoming Ecological Services)."
  chapter_identifier: great-plains
  create_dt: 2013-11-12T10:48:00
  href: http://52.38.26.42:8080/report/nca3/chapter/great-plains/figure/historical-and-current-range-of-sage-grouse-habitat.yaml
  identifier: historical-and-current-range-of-sage-grouse-habitat
  lat_max: ~
  lat_min: ~
  lon_max: ~
  lon_min: ~
  ordinal: 7
  report_identifier: nca3
  source_citation: 'adapted from Aldridge et al. 2008.<tbib>7c7085fc-ad53-4b51-8fa1-8856ae91c411</tbib> Photo credit: U.S. Fish and Wildlife Service, Wyoming Ecological Services'
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: Historical and Current Range of Sage Grouse Habitat
  uri: /report/nca3/chapter/great-plains/figure/historical-and-current-range-of-sage-grouse-habitat
  url: http://nca2014.globalchange.gov/report/regions/great-plains/graphics/historical-and-current-range-sage-grouse-habitat
  usage_limits: Free to use with credit to the original figure source.
- attributes: ~
  caption: "Demographic shifts continue to reshape communities in the Great Plains, with many\r\n    central Great Plains communities losing residents. Rural and tribal communities will face additional\r\n    challenges in dealing with climate change impacts due to demographic changes in the region (Ch. 14: Rural Communities; Ch. 12:\r\n    Indigenous Peoples). Figure shows population change from 2000 to 2010. (Figure source: U.S. Census Bureau\r\n    2010<tbib>469b861d-c8cb-49dd-839e-e68646ac8ba7</tbib>)."
  chapter_identifier: great-plains
  create_dt: 2013-11-12T11:04:00
  href: http://52.38.26.42:8080/report/nca3/chapter/great-plains/figure/population-change-in-the-great-plains.yaml
  identifier: population-change-in-the-great-plains
  lat_max: ~
  lat_min: ~
  lon_max: ~
  lon_min: ~
  ordinal: 8
  report_identifier: nca3
  source_citation: 'U.S. Census Bureau 2010<tbib>469b861d-c8cb-49dd-839e-e68646ac8ba7</tbib>'
  submission_dt: ~
  time_end: ~
  time_start: ~
  title: Population Change in the Great Plains
  uri: /report/nca3/chapter/great-plains/figure/population-change-in-the-great-plains
  url: http://nca2014.globalchange.gov/report/regions/great-plains/graphics/population-change-great-plains
  usage_limits: Free to use with credit to the original figure source.