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@prefix dcterms: <http://purl.org/dc/terms/> .
@prefix xsd: <http://www.w3.org/2001/XMLSchema#> .
@prefix gcis: <http://data.globalchange.gov/gcis.owl#> .
@prefix cito: <http://purl.org/spar/cito/> .
@prefix biro: <http://purl.org/spar/biro/> .
@prefix prov: <http://www.w3.org/ns/prov#> .

<https://data.globalchange.gov/report/nca3/chapter/energy-supply-and-use/table/energy-regional-impacts>
   dcterms:identifier "energy-regional-impacts";
   gcis:isTableOf <https://data.globalchange.gov/report/nca3>;
   gcis:tableNumber "4.1"^^xsd:string;
   dcterms:title "Changing Energy Use for Heating and Cooling Will Vary by Region"^^xsd:string;
   gcis:hasCaption "Hotter and longer summers will increase the amount of electricity necessary to run air conditioning, especially in the Southeast and Southwest. Warmer winters will decrease the amount of natural gas required to heat buildings, especially in the Northeast, Midwest, and Northwest. Table information is adapted from multi-model means from 8 NARCCAP regional climate simulations for the higher emissions scenario (A2) considered in this report and is weighted by population. (Source: adapted from Regional Climate Trends and Scenarios reports) "^^xsd:string;
   gcis:isTableOf <https://data.globalchange.gov/report/nca3/chapter/energy-supply-and-use>;

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<https://data.globalchange.gov/report/nca3/chapter/energy-supply-and-use/table/energy-regional-impacts>
   cito:cites <https://data.globalchange.gov/report/noaa-techreport-nesdis-142-1>;
   biro:references <https://data.globalchange.gov/reference/2acefcdc-827f-4c52-a4d8-56fc73f8ed35>.

<https://data.globalchange.gov/report/nca3/chapter/energy-supply-and-use/table/energy-regional-impacts>
   cito:cites <https://data.globalchange.gov/report/noaa-techreport-nesdis-142-6>;
   biro:references <https://data.globalchange.gov/reference/903f7ebb-9b60-4418-b617-593476cbcea5>.

<https://data.globalchange.gov/report/nca3/chapter/energy-supply-and-use/table/energy-regional-impacts>
   cito:cites <https://data.globalchange.gov/report/noaa-techreport-nesdis-142-3>;
   biro:references <https://data.globalchange.gov/reference/95f2ea7d-12e3-4ed5-9247-7cf139db91a9>.

<https://data.globalchange.gov/report/nca3/chapter/energy-supply-and-use/table/energy-regional-impacts>
   cito:cites <https://data.globalchange.gov/report/noaa-techreport-nesdis-142-5>;
   biro:references <https://data.globalchange.gov/reference/966bf116-8d6d-41f2-96be-4b66d3e729db>.

<https://data.globalchange.gov/report/nca3/chapter/energy-supply-and-use/table/energy-regional-impacts>
   cito:cites <https://data.globalchange.gov/report/noaa-techreport-nesdis-142-4>;
   biro:references <https://data.globalchange.gov/reference/994416dc-705b-4063-b8f5-bd3ed21d4a71>.

<https://data.globalchange.gov/report/nca3/chapter/energy-supply-and-use/table/energy-regional-impacts>
   cito:cites <https://data.globalchange.gov/report/noaa-techreport-nesdis-142-2>;
   biro:references <https://data.globalchange.gov/reference/b50d0bc7-8731-41e7-861c-b88b678f51d0>.