uri,href,identifier,attrs.Abstract,attrs.Author,attrs.DOI,attrs.Issue,attrs.Journal,attrs.Pages,attrs.Title,attrs.Volume,attrs.Year,attrs.\.reference_type,attrs._record_number,attrs._uuid,attrs.reftype,child_publication
/reference/2bdf925b-cb89-4bc8-b4bc-cc7568308582,https://data.globalchange.gov/reference/2bdf925b-cb89-4bc8-b4bc-cc7568308582,2bdf925b-cb89-4bc8-b4bc-cc7568308582,"Global sea level rises and falls as ice sheets and glaciers melt and grow, providing an integrated picture of the changes in ice volume but little information about how much individual ice fields are contributing to those variations. Knowing the regional structure of ice variability during glaciations and deglaciations will clarify the mechanisms of the glacial cycle. Clark et al. (p. 710) compiled and analyzed more than 5000 radiocarbon and cosmogenic surface exposure ages in order to develop a record of maximum regional ice extent around the time of the Last Glacial Maximum. The responses of the Northern and Southern Hemispheres differed significantly, which reveals how the evolution of specific ice sheets affected sea level and provides insight into how insolation controlled the deglaciation.We used 5704 14C, 10Be, and 3He ages that span the interval from 10,000 to 50,000 years ago (10 to 50 ka) to constrain the timing of the Last Glacial Maximum (LGM) in terms of global ice-sheet and mountain-glacier extent. Growth of the ice sheets to their maximum positions occurred between 33.0 and 26.5 ka in response to climate forcing from decreases in northern summer insolation, tropical Pacific sea surface temperatures, and atmospheric CO2. Nearly all ice sheets were at their LGM positions from 26.5 ka to 19 to 20 ka, corresponding to minima in these forcings. The onset of Northern Hemisphere deglaciation 19 to 20 ka was induced by an increase in northern summer insolation, providing the source for an abrupt rise in sea level. The onset of deglaciation of the West Antarctic Ice Sheet occurred between 14 and 15 ka, consistent with evidence that this was the primary source for an abrupt rise in sea level ~14.5 ka.","Clark, Peter U.; Dyke, Arthur S.; Shakun, Jeremy D.; Carlson, Anders E.; Clark, Jorie; Wohlfarth, Barbara; Mitrovica, Jerry X.; Hostetler, Steven W.; McCabe, A. Marshall",10.1126/science.1172873,5941,Science,710-714,"The last glacial maximum",325,2009,0,20766,2bdf925b-cb89-4bc8-b4bc-cc7568308582,"Journal Article",/article/10.1126/science.1172873
/reference/2c1cdc13-62d8-4e05-8e59-9002fc90a8f0,https://data.globalchange.gov/reference/2c1cdc13-62d8-4e05-8e59-9002fc90a8f0,2c1cdc13-62d8-4e05-8e59-9002fc90a8f0,,"NOAA RCC,",,,,,"xmACIS2 [Applied Climate Information System online tool]",,2017,16,24405,2c1cdc13-62d8-4e05-8e59-9002fc90a8f0,"Web Page",/webpage/394f087e-0b9e-491b-8dfe-b845314bf6c9
/reference/2db2b107-2e02-4f3a-b1e7-98301e28395d,https://data.globalchange.gov/reference/2db2b107-2e02-4f3a-b1e7-98301e28395d,2db2b107-2e02-4f3a-b1e7-98301e28395d,,"McNeill, Ryan; Nelson, Deborah J.; Wilson, Duff",,,,,"Water's edge: The crisis of rising sea levels",,2014,10,24016,2db2b107-2e02-4f3a-b1e7-98301e28395d,Report,/report/waters-edge-crisis-rising-sea-levels
/reference/2dd8b49c-000f-46c7-842d-634670416b61,https://data.globalchange.gov/reference/2dd8b49c-000f-46c7-842d-634670416b61,2dd8b49c-000f-46c7-842d-634670416b61,,"Deal, Nathan",,,,,"Deal declares state of emergency ahead of Hurricane Irma",,2017,63,26318,2dd8b49c-000f-46c7-842d-634670416b61,"Press Release",/generic/091dcb05-c325-4c91-b740-1b7bd1077c6f
/reference/2ddba35f-6036-4428-b4c7-800dd57b3313,https://data.globalchange.gov/reference/2ddba35f-6036-4428-b4c7-800dd57b3313,2ddba35f-6036-4428-b4c7-800dd57b3313,,"Hauer, Mathew E.",10.1038/nclimate3271,5,"Nature Climate Change",321-325,"Migration induced by sea-level rise could reshape the US population landscape",7,2017,,21812,2ddba35f-6036-4428-b4c7-800dd57b3313,"Journal Article",/article/10.1038/nclimate3271
/reference/2f36b977-b138-4bc4-893e-51f2fc519da0,https://data.globalchange.gov/reference/2f36b977-b138-4bc4-893e-51f2fc519da0,2f36b977-b138-4bc4-893e-51f2fc519da0,,"Cartwright, Jennifer M.; Wolfe, William J.",10.3133/pp1828,,,162,"Insular ecosystems of the southeastern United States: A regional synthesis to support biodiversity conservation in a changing climate",,2016,10,24438,2f36b977-b138-4bc4-893e-51f2fc519da0,Report,/report/insular-ecosystems-southeastern-united-states-regional-synthesis-support-biodiversity-conservation-changing-climate
/reference/2f417f1b-5cfa-42e1-b070-8852b2a3204b,https://data.globalchange.gov/reference/2f417f1b-5cfa-42e1-b070-8852b2a3204b,2f417f1b-5cfa-42e1-b070-8852b2a3204b,"Hurricanes Katrina and Rita showed the vulnerability of coastal communities and how human activities that caused deterioration of the Mississippi Deltaic Plain (MDP) exacerbated this vulnerability. The MDP formed by dynamic interactions between river and coast at various temporal and spatial scales, and human activity has reduced these interactions at all scales. Restoration efforts aim to re-establish this dynamic interaction, with emphasis on reconnecting the river to the deltaic plain. Science must guide MDP restoration, which will provide insights into delta restoration elsewhere and generally into coasts facing climate change in times of resource scarcity.","Day, J. W., Jr.; Boesch, D. F.; Clairain, E. J.; Kemp, G. P.; Laska, S. B.; Mitsch, W. J.; Orth, K.; Mashriqui, H.; Reed, D. J.; Shabman, L.; Simenstad, C. A.; Streever, B. J.; Twilley, R. R.; Watson, C. C.; Wells, J. T.; Whigham, D. F.",10.1126/science.1137030,5819,Science,1679-1684,"Restoration of the Mississippi Delta: Lessons from Hurricanes Katrina and Rita",315,2007,,6572,2f417f1b-5cfa-42e1-b070-8852b2a3204b,"Journal Article",/article/10.1126/science.1137030
/reference/30e64f09-40ad-4aa8-8a20-ecc203f91914,https://data.globalchange.gov/reference/30e64f09-40ad-4aa8-8a20-ecc203f91914,30e64f09-40ad-4aa8-8a20-ecc203f91914,,"Gabler, Christopher A.; Osland, Michael J.; Grace, James B.; Stagg, Camille L.; Day, Richard H.; Hartley, Stephen B.; Enwright, Nicholas M.; From, Andrew S.; McCoy, Meagan L.; McLeod, Jennie L.",10.1038/nclimate3203,,"Nature Climate Change",142-147,"Macroclimatic change expected to transform coastal wetland ecosystems this century",7,2017,,24317,30e64f09-40ad-4aa8-8a20-ecc203f91914,"Journal Article",/article/10.1038/nclimate3203
/reference/31446ba7-4409-483b-b467-ae773a9ba950,https://data.globalchange.gov/reference/31446ba7-4409-483b-b467-ae773a9ba950,31446ba7-4409-483b-b467-ae773a9ba950,,"Osland, Michael J.; Enwright, Nicholas; Day, Richard H.; Doyle, Thomas W.",10.1111/gcb.12126,5,"Global Change Biology",1482-1494,"Winter climate change and coastal wetland foundation species: Salt marshes vs. mangrove forests in the southeastern United States",19,2013,,23430,31446ba7-4409-483b-b467-ae773a9ba950,"Journal Article",/article/10.1111/gcb.12126
/reference/342449f8-d0b7-4653-a926-cf791f393658,https://data.globalchange.gov/reference/342449f8-d0b7-4653-a926-cf791f393658,342449f8-d0b7-4653-a926-cf791f393658,,"Provancha, Mark J.; Paul A. Schmalzer; Carlton R. Hall",,4,"Florida Scientist",199-212,"Effects of the December 1983 and January 1985 freezing air temperatures on select aquatic poikilotherms and plant species of Merritt Island, Florida.",49,1986,,24369,342449f8-d0b7-4653-a926-cf791f393658,"Journal Article",/article/effects-december-1983-january-1985-freezing-air-temperatures-on-select-aquatic-poikilotherms-plant-species-merritt-island-florida
/reference/34475656-1ce9-404c-a149-cdc198c34b95,https://data.globalchange.gov/reference/34475656-1ce9-404c-a149-cdc198c34b95,34475656-1ce9-404c-a149-cdc198c34b95,,"Costanza, Robert; de Groot, Rudolf; Sutton, Paul; van der Ploeg, Sander; Anderson, Sharolyn J.; Kubiszewski, Ida; Farber, Stephen; Turner, R. Kerry",10.1016/j.gloenvcha.2014.04.002,,"Global Environmental Change",152-158,"Changes in the global value of ecosystem services",26,2014,,24303,34475656-1ce9-404c-a149-cdc198c34b95,"Journal Article",/article/10.1016/j.gloenvcha.2014.04.002
/reference/345ce7da-0d5f-4840-b8d5-886be49a92cb,https://data.globalchange.gov/reference/345ce7da-0d5f-4840-b8d5-886be49a92cb,345ce7da-0d5f-4840-b8d5-886be49a92cb,"The climate change-induced expansion of mangroves into salt marshes could significantly alter the carbon (C) storage capacity of coastal wetlands, which have the highest average C storage per land area among unmanaged terrestrial ecosystems. Mangrove range expansion is occurring globally, but little is known about how these rapid climate-driven shifts may alter ecosystem C storage. Here, we quantify current C stocks in ecotonal wetlands across gradients of marsh- to mangrove-dominance, and use unique chronological maps of vegetation cover to estimate C stock changes from 2003 to 2010 in a 567-km2 wildlife refuge in the mangrove-salt marsh ecotone. We report that over the 7-yr. period, total wetland C stocks increased 22 % due to mangrove encroachment into salt marshes. Newly established mangrove stands stored twice as much C on a per area basis as salt marsh primarily due to differences in aboveground biomass, and mangrove cover increased by 69 % during this short time interval. Wetland C storage within the wildlife refuge increased at a rate of 2.7 Mg C ha−1 yr.−1, more than doubling the naturally high coastal wetland C sequestration rates. Mangrove expansion could account for a globally significant increase of terrestrial C storage, which may exert a considerable negative feedback on warming.","Doughty, Cheryl L.; Langley, J. Adam; Walker, Wayne S.; Feller, Ilka C.; Schaub, Ronald; Chapman, Samantha K.",10.1007/s12237-015-9993-8,2,"Estuaries and Coasts",385-396,"Mangrove range expansion rapidly increases coastal wetland carbon storage",39,2016,,24310,345ce7da-0d5f-4840-b8d5-886be49a92cb,"Journal Article",/article/10.1007/s12237-015-9993-8
/reference/354d0cf6-ed50-47c4-8fa7-1b8a0f2f6672,https://data.globalchange.gov/reference/354d0cf6-ed50-47c4-8fa7-1b8a0f2f6672,354d0cf6-ed50-47c4-8fa7-1b8a0f2f6672,,"Field, Donald W.; Reyer, Anthony J.; Genovese, Paul V.; Shearer, Beth D.",,,,59,"Coastal wetlands of the United States: An accounting of a valuable national resource",,1991,10,24419,354d0cf6-ed50-47c4-8fa7-1b8a0f2f6672,Report,/report/coastal-wetlands-united-states-an-accounting-valuable-national-resource
/reference/358c837b-cfe8-45ac-935c-ad9a89aed543,https://data.globalchange.gov/reference/358c837b-cfe8-45ac-935c-ad9a89aed543,358c837b-cfe8-45ac-935c-ad9a89aed543,,"Robinet, Christelle; Roques, Alain",10.1111/j.1749-4877.2010.00196.x,2,"Integrative Zoology",132-142,"Direct impacts of recent climate warming on insect populations",5,2010,,24372,358c837b-cfe8-45ac-935c-ad9a89aed543,"Journal Article",/article/10.1111/j.1749-4877.2010.00196.x
/reference/36ca022b-b59b-405a-a575-f21196e2bfe1,https://data.globalchange.gov/reference/36ca022b-b59b-405a-a575-f21196e2bfe1,36ca022b-b59b-405a-a575-f21196e2bfe1,,"Doyle, Thomas W.; Girod, Garrett F.; Books, Mark A.",,,,211-222,"Modeling mangrove forest migration along the southwest coast of Florida under climate change",,2003,7,24429,36ca022b-b59b-405a-a575-f21196e2bfe1,"Book Section",/book/c89a36fc-d70f-47e7-8adc-e3cbd6cb5bda
/reference/37ed4780-fbaa-4fd1-ba73-9285e8a06b45,https://data.globalchange.gov/reference/37ed4780-fbaa-4fd1-ba73-9285e8a06b45,37ed4780-fbaa-4fd1-ba73-9285e8a06b45,"Urban green space (UGS) is widely espoused in sustainable urban design. Notwithstanding its ecosystem services, UGS is commonly perceived as inadvertent habitats for urban mosquitoes. Moreover, the lack of ecological understanding of mosquitoes and their urban habitats renders vector control in green spaces without reliance on chemical and bio-pesticides especially challenging.","Wong, Gwendolyn K. L.; Jim, C. Y.",10.1007/s10980-018-0616-1,3,"Landscape Ecology",475-489,"Abundance of urban male mosquitoes by green infrastructure types: Implications for landscape design and vector management",33,2018,,26302,37ed4780-fbaa-4fd1-ba73-9285e8a06b45,"Journal Article",/article/10.1007/s10980-018-0616-1
/reference/3994dfa3-042a-41bc-b976-8e5a99ddba12,https://data.globalchange.gov/reference/3994dfa3-042a-41bc-b976-8e5a99ddba12,3994dfa3-042a-41bc-b976-8e5a99ddba12,,"Desantis, Larisa R. G.; Bhotika, Smriti; Williams, Kimberlyn; Putz, Francis E.",10.1111/j.1365-2486.2007.01440.x,11,"Global Change Biology",2349-2360,"Sea-level rise and drought interactions accelerate forest decline on the Gulf Coast of Florida, USA",13,2007,,24307,3994dfa3-042a-41bc-b976-8e5a99ddba12,"Journal Article",/article/10.1111/j.1365-2486.2007.01440.x
/reference/3a22fe4f-b6fe-471a-b471-9728b5799689,https://data.globalchange.gov/reference/3a22fe4f-b6fe-471a-b471-9728b5799689,3a22fe4f-b6fe-471a-b471-9728b5799689,,"Ferrario, Filippo; Beck, Michael W.; Storlazzi, Curt D.; Micheli, Fiorenza; Shepard, Christine C.; Airoldi, Laura",10.1038/ncomms4794,,"Nature Communications",3794,"The effectiveness of coral reefs for coastal hazard risk reduction and adaptation",5,2014,,24030,3a22fe4f-b6fe-471a-b471-9728b5799689,"Journal Article",/article/10.1038/ncomms4794
/reference/3a87a3e6-3e40-4a5d-8b61-2071f8cfadbe,https://data.globalchange.gov/reference/3a87a3e6-3e40-4a5d-8b61-2071f8cfadbe,3a87a3e6-3e40-4a5d-8b61-2071f8cfadbe,,"Ungerer, Matthew J.; Ayres, Matthew P.; Lombardero, María J.",10.1046/j.1365-2699.1999.00363.x,6,"Journal of Biogeography",1133-1145,"Climate and the northern distribution limits of Dendroctonus frontalis Zimmermann (Coleoptera: Scolytidae)",26,1999,,24387,3a87a3e6-3e40-4a5d-8b61-2071f8cfadbe,"Journal Article",/article/10.1046/j.1365-2699.1999.00363.x
/reference/3bae2310-7572-47e2-99a4-9e4276764934,https://data.globalchange.gov/reference/3bae2310-7572-47e2-99a4-9e4276764934,3bae2310-7572-47e2-99a4-9e4276764934,,"Sweet, W.V.; R. Horton; R.E. Kopp; A.N. LeGrande; A. Romanou",10.7930/J0VM49F2,,,333-363,"Sea Level Rise",,2017,7,21570,3bae2310-7572-47e2-99a4-9e4276764934,"Book Section",/report/climate-science-special-report/chapter/sea-level-rise
/reference/3bb5e821-3496-48fd-88ff-d0357e0d39f4,https://data.globalchange.gov/reference/3bb5e821-3496-48fd-88ff-d0357e0d39f4,3bb5e821-3496-48fd-88ff-d0357e0d39f4,,"Maldonado, Julie K.; Kristina Peterson",,,,289-299,"A community-based model for resettlement: Lessons from coastal Louisiana ",,2018,7,24348,3bb5e821-3496-48fd-88ff-d0357e0d39f4,"Book Section",/book/d64a5775-ab78-48c3-b458-208774e61c72
/reference/3bffd087-0af7-47d7-8a00-a21f0fc63569,https://data.globalchange.gov/reference/3bffd087-0af7-47d7-8a00-a21f0fc63569,3bffd087-0af7-47d7-8a00-a21f0fc63569,"Mangroves occur on upper intertidal shorelines in the tropics and subtropics. Complex hydrodynamic and salinity conditions, related primarily to elevation and hydroperiod, influence mangrove distributions; this review considers how these distributions change over time. Accumulation rates of allochthonous and autochthonous sediment, both inorganic and organic, vary between and within different settings. Abundant terrigenous sediment can form dynamic mudbanks, and tides redistribute sediment, contrasting with mangrove peat in sediment-starved carbonate settings. Sediments underlying mangroves sequester carbon but also contain paleoenvironmental records of adjustments to past sea-level changes. Radiometric dating indicates long-term sedimentation, whereas measurements made using surface elevation tables and marker horizons provide shorter perspectives, indicating shallow subsurface processes of root growth and substrate autocompaction. Many tropical deltas also experience deep subsidence, which augments relative sea-level rise. The persistence of mangroves implies an ability to cope with moderately high rates of relative sea-level rise. However, many human pressures threaten mangroves, resulting in a continuing decline in their extent throughout the tropics.*","Woodroffe, C. D.; Rogers, K.; McKee, K. L.; Lovelock, C. E.; Mendelssohn, I. A.; Saintilan, N.",10.1146/annurev-marine-122414-034025,1,"Annual Review of Marine Science",243-266,"Mangrove sedimentation and response to relative sea-level rise",8,2016,,22544,3bffd087-0af7-47d7-8a00-a21f0fc63569,"Journal Article",/article/10.1146/annurev-marine-122414-034025
/reference/3d02cd74-3620-4b87-84f2-427c8ed914c5,https://data.globalchange.gov/reference/3d02cd74-3620-4b87-84f2-427c8ed914c5,3d02cd74-3620-4b87-84f2-427c8ed914c5,,"WUCA Strategic Planning Committee,",,,,6,"Water Utility Climate Alliance 2017–2021 Strategic Plan",,2016,10,24401,3d02cd74-3620-4b87-84f2-427c8ed914c5,Report,/report/water-utility-climate-alliance-20172021-strategic-plan
/reference/3d6ed603-cc6d-4c77-b35d-4bd62121d82e,https://data.globalchange.gov/reference/3d6ed603-cc6d-4c77-b35d-4bd62121d82e,3d6ed603-cc6d-4c77-b35d-4bd62121d82e,,"Lewis, Courtney",10.1353/scu.2012.0019,2,"Southern Cultures",104-117,"The case of the wild onions: The impact of ramps on Cherokee rights",18,2012,,24412,3d6ed603-cc6d-4c77-b35d-4bd62121d82e,"Journal Article",/article/10.1353/scu.2012.0019