uri,href,identifier,attributes,caption,chapter_identifier,create_dt,lat_max,lat_min,lon_max,lon_min,ordinal,report_identifier,source_citation,submission_dt,time_end,time_start,title,url,usage_limits
/report/climate-science-special-report/chapter/ocean-acidification/figure/ocean-heat-uptake,https://data.globalchange.gov/report/climate-science-special-report/chapter/ocean-acidification/figure/ocean-heat-uptake,ocean-heat-uptake,,"Global Ocean heat content change time series. Ocean heat content from 0 to 700 m (blue), 700 to 2,000 m (red), and 0 to 2,000 m (dark gray) from 1955 to 2015 with an uncertainty interval of ±2 standard deviations shown in shading. All time series of the analysis performed by Cheng et al.<tbib>db777261-ee2e-4bf6-944e-a8831c595300</tbib> are smoothed by a 12-month running mean filter, relative to the 1997–2005 base period.   (Figure source: Cheng et al. 2017<tbib>db777261-ee2e-4bf6-944e-a8831c595300</tbib>).",ocean-acidification,2017-03-28T20:10:35,,,,,1,climate-science-special-report,,2017-09-01T20:51:48,,,"Ocean Heat Uptake",,"Free to use with credit to the original figure source."
/report/climate-science-special-report/chapter/ocean-acidification/figure/trends-in-ocean-heat-content-for-different-ocean-basins,https://data.globalchange.gov/report/climate-science-special-report/chapter/ocean-acidification/figure/trends-in-ocean-heat-content-for-different-ocean-basins,trends-in-ocean-heat-content-for-different-ocean-basins,,"Ocean heat content changes from 1960 to 2015 for different ocean basins for 0 to 2,000 m depths. Time series is relative to the 1997–1999 base period and smoothed by a 12-month running filter by Cheng et al.<tbib>db777261-ee2e-4bf6-944e-a8831c595300</tbib> The curves are additive, and the ocean heat content changes in different ocean basins are shaded in different colors   (Figure source: Cheng et al. 2017<tbib>db777261-ee2e-4bf6-944e-a8831c595300</tbib>).",ocean-acidification,2017-04-07T13:35:49,,,,,2,climate-science-special-report,,2017-09-01T20:52:46,,,"Ocean Heat Content",,"Free to use with credit to the original figure source."
/report/climate-science-special-report/chapter/ocean-acidification/figure/projection,https://data.globalchange.gov/report/climate-science-special-report/chapter/ocean-acidification/figure/projection,projection,,"Projected changes in sea surface temperature (°C) for the coastal United States under the higher scenario (RCP8.5). Projected anomalies for the 2050–2099 period are calculated using a comparison from the average sea surface temperatures over 1956–2005. Projected changes are examined using the Coupled Model Intercomparison Project Phase 5 (CMIP5) suite of model simulations.   (Figure source: NOAA). ",ocean-acidification,2017-04-12T15:37:30,,,,,3,climate-science-special-report,,2017-09-01T20:55:07,,,"Projected Changes in SST",,"Free to use with credit to the original figure source."
/report/climate-science-special-report/chapter/ocean-acidification/figure/hot-data-20160721,https://data.globalchange.gov/report/climate-science-special-report/chapter/ocean-acidification/figure/hot-data-20160721,hot-data-20160721,,"Trends in surface (&lt; 50 m) ocean carbonate chemistry calculated from observations obtained at the Hawai‘i Ocean Time-series (HOT) Program in the North Pacific over 1988–2015. The upper panel shows the linked increase in atmospheric (red points) and seawater (blue points) CO<sub>2</sub> concentrations. The bottom panel shows a decline in seawater pH (black points, primary y-axis) and carbonate ion concentration (green points, secondary y-axis). Ocean chemistry data were obtained from the Hawai‘i Ocean Time-series Data Organization &amp; Graphical System (HOT-DOGS, <a href=""http://hahana.soest.hawaii.edu/hot/hot-dogs/index.html"">http://hahana.soest.hawaii.edu</a>).   (Figure source: NOAA).",ocean-acidification,2016-09-02T17:01:38,,,,,4,climate-science-special-report,,2017-10-31T16:44:43,,,"Ocean Carbonate Chemistry",,"Free to use with credit to the original figure source."
/report/climate-science-special-report/chapter/ocean-acidification/figure/acidif_future_fig3,https://data.globalchange.gov/report/climate-science-special-report/chapter/ocean-acidification/figure/acidif_future_fig3,acidif_future_fig3,,"Predicted change in sea surface pH in 2090–2099 relative to 1990–1999 under the higher scenario (RCP8.5), based on the Community Earth System Models–Large Ensemble Experiments CMIP5   (Figure source: adapted from Bopp et al. 2013<tbib>fa10bfab-8f7c-4d8c-8435-8284a05d78e5</tbib>).",ocean-acidification,2016-11-11T21:55:22,,,,,5,climate-science-special-report,,2017-09-01T20:59:47,,,"Surface pH in 2090s",,"Free to use with credit to the original figure source."
/report/climate-science-special-report/chapter/ocean-acidification/figure/04-state-map-change-o2-iage,https://data.globalchange.gov/report/climate-science-special-report/chapter/ocean-acidification/figure/04-state-map-change-o2-iage,04-state-map-change-o2-iage,,"Predicted change in dissolved oxygen on the σ<sub>θ</sub> = 26.5 (average depth of approximately 290 m) potential density surface, between the 1981–2000 and 2081–2100, based on the Community Earth System Models–Large Ensemble Experiments (Figure source: redrawn from Long et al. 2016<tbib>d04b2c86-5ca0-42e0-9792-2f319c15cd7e</tbib>).",ocean-acidification,2016-09-02T17:01:07,,,,,6,climate-science-special-report,,2017-09-14T18:32:44,,,"Dissolved Oxygen",,"Free to use with credit to the original figure source."