{"status":"ok","message-type":"work","message-version":"1.0.0","message":{"indexed":{"date-parts":[[2026,4,10]],"date-time":"2026-04-10T14:46:04Z","timestamp":1775832364257,"version":"3.50.1"},"reference-count":60,"publisher":"MDPI AG","issue":"5","license":[{"start":{"date-parts":[[2021,2,25]],"date-time":"2021-02-25T00:00:00Z","timestamp":1614211200000},"content-version":"vor","delay-in-days":0,"URL":"https:\/\/creativecommons.org\/licenses\/by\/4.0\/"}],"funder":[{"DOI":"10.13039\/100000001","name":"National Science Foundation","doi-asserted-by":"publisher","award":["1928048"],"award-info":[{"award-number":["1928048"]}],"id":[{"id":"10.13039\/100000001","id-type":"DOI","asserted-by":"publisher"}]},{"DOI":"10.13039\/100000001","name":"National Science Foundation","doi-asserted-by":"publisher","award":["1927772"],"award-info":[{"award-number":["1927772"]}],"id":[{"id":"10.13039\/100000001","id-type":"DOI","asserted-by":"publisher"}]}],"content-domain":{"domain":[],"crossmark-restriction":false},"short-container-title":["Remote Sensing"],"abstract":"Nearly 25% of all lakes on earth are located at high latitudes. These lakes are formed by a combination of thermokarst, glacial, and geological processes. Evidence suggests that the origin of periglacial lake formation may be an important factor controlling the likelihood of lakes to drain. However, geospatial data regarding the spatial distribution of these dominant Arctic and subarctic lakes are limited or do not exist. Here, we use lake-specific morphological properties using the Arctic Digital Elevation Model (DEM) and Landsat imagery to develop a Thermokarst lake Settlement Index (TSI), which was used in combination with available geospatial datasets of glacier history and yedoma permafrost extent to classify Arctic and subarctic lakes into Thermokarst (non-yedoma), Yedoma, Glacial, and Maar lakes, respectively. This lake origin dataset was used to evaluate the influence of lake origin on drainage between 1985 and 2019 in northern Alaska. The lake origin map and lake drainage datasets were synthesized using five-year seamless Landsat ETM+ and OLI image composites. Nearly 35,000 lakes and their properties were characterized from Landsat mosaics using an object-based image analysis. Results indicate that the pattern of lake drainage varied by lake origin, and the proportion of lakes that completely drained (i.e., >60% area loss) between 1985 and 2019 in Thermokarst (non-yedoma), Yedoma, Glacial, and Maar lakes were 12.1, 9.5, 8.7, and 0.0%, respectively. The lakes most vulnerable to draining were small thermokarst (non-yedoma) lakes (12.7%) and large yedoma lakes (12.5%), while the most resilient were large and medium-sized glacial lakes (4.9 and 4.1%) and Maar lakes (0.0%). This analysis provides a simple remote sensing approach to estimate the spatial distribution of dominant lake origins across variable physiography and surficial geology, useful for discriminating between vulnerable versus resilient Arctic and subarctic lakes that are likely to change in warmer and wetter climates.<\/jats:p>","DOI":"10.3390\/rs13050852","type":"journal-article","created":{"date-parts":[[2021,2,26]],"date-time":"2021-02-26T04:36:24Z","timestamp":1614314184000},"page":"852","update-policy":"https:\/\/doi.org\/10.3390\/mdpi_crossmark_policy","source":"Crossref","is-referenced-by-count":9,"title":["Periglacial Lake Origin Influences the Likelihood of Lake Drainage in Northern Alaska"],"prefix":"10.3390","volume":"13","author":[{"ORCID":"https:\/\/orcid.org\/0000-0002-4670-7031","authenticated-orcid":false,"given":"Mark Jason","family":"Lara","sequence":"first","affiliation":[{"name":"Department of Plant Biology, University of Illinois, Urbana, IL 61801, USA"},{"name":"Department of Geography, University of Illinois, Urbana, IL 61801, USA"}]},{"ORCID":"https:\/\/orcid.org\/0000-0002-6872-8829","authenticated-orcid":false,"given":"Melissa Lynn","family":"Chipman","sequence":"additional","affiliation":[{"name":"Department of Earth and Environmental Sciences, Syracuse University, Syracuse, NY 13244, USA"}]}],"member":"1968","published-online":{"date-parts":[[2021,2,25]]},"reference":[{"key":"ref_1","doi-asserted-by":"crossref","unstructured":"Verpoorter, C., Kutser, T., Seekell, D.A., and Tranvik, L.J. (2014). A Global Inventory of Lakes Based on High-Resolution Satellite Imagery. Geophys. Res. Lett.","DOI":"10.1002\/2014GL060641"},{"key":"ref_2","doi-asserted-by":"crossref","unstructured":"Messager, M.L., Lehner, B., Grill, G., Nedeva, I., and Schmitt, O. (2016). Estimating the Volume and Age of Water Stored in Global Lakes Using a Geo-Statistical Approach. Nat. Commun.","DOI":"10.1038\/ncomms13603"},{"key":"ref_3","doi-asserted-by":"crossref","unstructured":"Arp, C.D., and Jones, B.M. (2020, October 15). Geography of Alaska Lake Districts: Identification, Description, and Analysis of Lake-Rich Regions of a Diverse and Dynamic State. U.S. Geological Survey. Scientific Investigations Report 2008-5215, Available online: https:\/\/pubs.usgs.gov\/sir\/2008\/5215\/.","DOI":"10.3133\/sir20085215"},{"key":"ref_4","unstructured":"Everdingen, R.O. (2020, November 15). Van Multi-Language Glossary of Permafrost and Related Ground-Ice Terms (Rev. Ed.). International Permafrost Association. Available online: http:\/\/globalcryospherewatch.org\/reference\/glossary_docs\/Glossary_of_Permafrost_and_Ground-Ice_IPA_2005.pdf."},{"key":"ref_5","doi-asserted-by":"crossref","unstructured":"Pullman, E.R., Jorgenson, M.T., and Shur, Y. (2007). Thaw Settlement in Soils of the Arctic Coastal Plain, Alaska. Arctic Antarct. Alp. Res.","DOI":"10.1657\/1523-0430(05-045)[PULLMAN]2.0.CO;2"},{"key":"ref_6","doi-asserted-by":"crossref","unstructured":"Jones, B.M., Grosse, G., Arp, C.D., Jones, M.C., Walter Anthony, K.M., and Romanovsky, V.E. (2011). Modern Thermokarst Lake Dynamics in the Continuous Permafrost Zone, Northern Seward Peninsula, Alaska. J. Geophys. Res. Biogeosci.","DOI":"10.1029\/2011JG001666"},{"key":"ref_7","unstructured":"Shur, Y.L., Kanevskiy, M., Jorgenson, M.T., Dillon, M., Stephani, E., Bray, M., and Fortier, D. (2012, January 25\u201329). Permafrost Degradation and Thaw Settlement under Lakes in Yedoma Environment. Proceedings of the Tenth International Conference on Permafrost, Salekhard, Russia."},{"key":"ref_8","doi-asserted-by":"crossref","unstructured":"Farquharson, L.M., Mann, D.H., Grosse, G., Jones, B.M., and Romanovsky, V.E. (2016). Spatial Distribution of Thermokarst Terrain in Arctic Alaska. Geomorphology.","DOI":"10.1016\/j.geomorph.2016.08.007"},{"key":"ref_9","doi-asserted-by":"crossref","unstructured":"Henriksen, M., Mangerud, J., Matiouchkov, A., Paus, A., and Svendsen John Inge, I. (2003). Lake Stratigraphy Implies an 80 000 Yr Delayed Melting of Buried Dead Ice in Northern Russia. J. Quat. Sci.","DOI":"10.1002\/jqs.788"},{"key":"ref_10","doi-asserted-by":"crossref","unstructured":"Hinkel, K.M., Sheng, Y., Lenters, J.D., Lyons, E.A., Beck, R.A., Eisner, W.R., and Wang, J. (2012). Thermokarst Lakes on the Arctic Coastal Plain of Alaska: Geomorphic Controls on Bathymetry. Permafr. Periglac. Process.","DOI":"10.1002\/ppp.1744"},{"key":"ref_11","first-page":"325","article-title":"Thermokarst Lakes, Drainage, and Drained Basins","volume":"Volume 8","author":"Shroder","year":"2013","journal-title":"Treatise on Geomorphology"},{"key":"ref_12","doi-asserted-by":"crossref","unstructured":"Rouse, W.R., Oswald, C.J., Binyamin, J., Spence, C., Schertzer, W.M., Blanken, P.D., Bussi\u00e8res, N., and Duguay, C.R. (2005). The Role of Northern Lakes in a Regional Energy Balance. J. Hydrometeorol.","DOI":"10.1175\/JHM421.1"},{"key":"ref_13","doi-asserted-by":"crossref","first-page":"359","DOI":"10.1579\/0044-7447(2006)35[359:CCEOAB]2.0.CO;2","article-title":"Climate Change Effects on Aquatic Biota, Ecosystem Structure and Function","volume":"35","author":"Wrona","year":"2006","journal-title":"AMBIO"},{"key":"ref_14","doi-asserted-by":"crossref","unstructured":"Larsen, A.S., O\u2019Donnell, J.A., Schmidt, J.H., Kristenson, H.J., and Swanson, D.K. (2017). Physical and Chemical Characteristics of Lakes across Heterogeneous Landscapes in Arctic and Subarctic Alaska. J. Geophys. Res. Biogeosci.","DOI":"10.1002\/2016JG003729"},{"key":"ref_15","doi-asserted-by":"crossref","unstructured":"Lewis, T.L., Lindberg, M.S., Schmutz, J.A., Heglund, P.J., Rover, J., Koch, J.C., and Bertram, M.R. (2015). Pronounced Chemical Response of Subarctic Lakes to Climate-Driven Losses in Surface Area. Glob. Chang. Biol.","DOI":"10.1111\/gcb.12759"},{"key":"ref_16","doi-asserted-by":"crossref","unstructured":"Deshpande, B.N., Macintyre, S., Matveev, A., and Vincent, W.F. (2015). Oxygen Dynamics in Permafrost Thaw Lakes: Anaerobic Bioreactors in the Canadian Subarctic. Limnol. Oceanogr.","DOI":"10.1002\/lno.10126"},{"key":"ref_17","doi-asserted-by":"crossref","unstructured":"Swanson, D.K. (2019). Thermokarst and Precipitation Drive Changes in the Area of Lakes and Ponds in the National Parks of Northwestern Alaska, 1984\u20132018. Arctic Antarct. Alp. Res.","DOI":"10.1080\/15230430.2019.1629222"},{"key":"ref_18","doi-asserted-by":"crossref","unstructured":"Nitze, I., Cooley, S.W., R. Duguay, C., Jones, M.B., and Grosse, G. (2020). The Catastrophic Thermokarst Lake Drainage Events of 2018 in Northwestern Alaska: Fast-Forward into the Future. Cryosphere.","DOI":"10.5194\/tc-2020-106"},{"key":"ref_19","unstructured":"Nowacki, G., Spencer, P., Brock, T., Fleming, M., and Jorgenson, M.T. (2001). Unified Ecoregions of Alaska and Neighboring Territories."},{"key":"ref_20","doi-asserted-by":"crossref","unstructured":"Raynolds, M.K., Walker, D.A., Balser, A., Bay, C., Campbell, M., Cherosov, M.M., Dani\u00ebls, F.J.A., Eidesen, P.B., Ermokhina, K.A., and Frost, G.V. (2019). A Raster Version of the Circumpolar Arctic Vegetation Map (CAVM). Remote Sens. Environ.","DOI":"10.1016\/j.rse.2019.111297"},{"key":"ref_21","unstructured":"Jorgenson, T.M., Yoshikawa, K., Kanevskiy, M., Shur, Y., Marchenko, S., and Jones, B. (July, January 29). Permafrost Characteristics of Alaska. Proceedings of the Ninth International Conference on Permafrost, Fairbanks, AK, USA."},{"key":"ref_22","unstructured":"Jorgenson, M.T., Shur, Y., Kanevskiy, M.Z., Grunblatt, J., Michaelson, G., and Ping, C.-L. (2014). Permafrost Database Development, Characterization, and Mapping for Northern Alaska."},{"key":"ref_23","unstructured":"Jorgenson, M.T., Roth, J.E., Emers, M., Davis, W.A., Schlentner, S.F., and Macander, M.J. (2004). Landcover Mapping for Bering Land Bridge National Preserve and Cape Krusenstern."},{"key":"ref_24","doi-asserted-by":"crossref","unstructured":"Carson, C.E., and Hussey, K.M. (1962). The Oriented Lakes of Arctic Alaska. J. Geol.","DOI":"10.1086\/626834"},{"key":"ref_25","doi-asserted-by":"crossref","unstructured":"Pelletier, J.D. (2005). Formation of Oriented Thaw Lakes by Thaw Slumping. J. Geophys. Res. Earth Surf.","DOI":"10.1029\/2004JF000158"},{"key":"ref_26","doi-asserted-by":"crossref","unstructured":"Schirrmeister, L., Kunitsky, V., Grosse, G., Wetterich, S., Meyer, H., Schwamborn, G., Babiy, O., Derevyagin, A., and Siegert, C. (2011). Sedimentary Characteristics and Origin of the Late Pleistocene Ice Complex on North-East Siberian Arctic Coastal Lowlands and Islands\u2014A Review. Quat. Int.","DOI":"10.1016\/j.quaint.2010.04.004"},{"key":"ref_27","doi-asserted-by":"crossref","unstructured":"Pewe, T.L. (1975). US Government Printing Office. Quaternary Geology of Alaska, Geological Survey Professional Paper.","DOI":"10.3133\/pp835"},{"key":"ref_28","doi-asserted-by":"crossref","unstructured":"Fraser, T.A., and Burn, C.R. (1997). On the Nature and Origin of \u201cMuck\u201d Deposits in the Klondike Area, Yukon Territory. Can. J. Earth Sci.","DOI":"10.1139\/e17-106"},{"key":"ref_29","doi-asserted-by":"crossref","unstructured":"Kauman, D.S., and Manley, W.F. (2004). Pleistocene Maximum and Late Wisconsinan Glacier Extents across Alaska, U.S.A. Dev. Quat. Sci.","DOI":"10.1016\/S1571-0866(04)80182-9"},{"key":"ref_30","doi-asserted-by":"crossref","unstructured":"Morgenstern, A., Grosse, G., G\u00fcnther, F., Fedorova, I., and Schirrmeister, L. (2011). Spatial Analyses of Thermokarst Lakes and Basins in Yedoma Landscapes of the Lena Delta. Cryosphere.","DOI":"10.5194\/tcd-5-1495-2011"},{"key":"ref_31","doi-asserted-by":"crossref","unstructured":"Strauss, J., Schirrmeister, L., Wetterich, S., Borchers, A., and Davydov, S.P. (2012). Grain-Size Properties and Organic-Carbon Stock of Yedoma Ice Complex Permafrost from the Kolyma Lowland, Northeastern Siberia. Global Biogeochem. Cycles.","DOI":"10.1029\/2011GB004104"},{"key":"ref_32","doi-asserted-by":"crossref","unstructured":"Kanevskiy, M., Shur, Y., Fortier, D., Jorgenson, M.T., and Stephani, E. (2011). Cryostratigraphy of Late Pleistocene Syngenetic Permafrost (Yedoma) in Northern Alaska, Itkillik River Exposure. Quat. Res.","DOI":"10.1016\/j.yqres.2010.12.003"},{"key":"ref_33","doi-asserted-by":"crossref","unstructured":"Beg\u00e9t, J.E., Hopkins, D.M., and Charron, S.D. (1996). The Largest Known Maars on Earth, Seward Peninsula, Northwest Alaska. Arctic.","DOI":"10.14430\/arctic1184"},{"key":"ref_34","doi-asserted-by":"crossref","unstructured":"Nitze, I., Grosse, G., Jones, B.M., Romanovsky, V.E., and Boike, J. (2018). Remote Sensing Quantifies Widespread Abundance of Permafrost Region Disturbances across the Arctic and Subarctic. Nat. Commun.","DOI":"10.1038\/s41467-018-07663-3"},{"key":"ref_35","doi-asserted-by":"crossref","unstructured":"Jones, B.M., Arp, C.D., Grosse, G., Nitze, I., Lara, M.J., Whitman, M.S., Farquharson, L.M., Kanevskiy, M., Parsekian, A.D., and Breen, A.L. (2020). Identifying Historical and Future Potential Lake Drainage Events on the Western Arctic Coastal Plain of Alaska. Permafr. Periglac. Process.","DOI":"10.1002\/ppp.2038"},{"key":"ref_36","doi-asserted-by":"crossref","first-page":"145","DOI":"10.1002\/hyp.7179","article-title":"Changes in Thaw Lake Drainage in the Western Canadian Arctic from 1950 to 2000","volume":"23","author":"Marsh","year":"2009","journal-title":"Hydrol. Process."},{"key":"ref_37","doi-asserted-by":"crossref","unstructured":"Lara, M.J., Chipman, M.L., and Hu, F.S. (2019). Automated Detection of Thermoerosion in Permafrost Ecosystems Using Temporally Dense Landsat Image Stacks. Remote Sens. Environ.","DOI":"10.1016\/j.rse.2018.11.034"},{"key":"ref_38","doi-asserted-by":"crossref","unstructured":"Lara, M.J., Nitze, I., Grosse, G., Martin, P., and David McGuire, A. (2018). Reduced Arctic Tundra Productivity Linked with Landform and Climate Change Interactions. Sci. Rep.","DOI":"10.1038\/s41598-018-20692-8"},{"key":"ref_39","doi-asserted-by":"crossref","unstructured":"Lara, M.J., Nitze, I., Grosse, G., and David McGuire, A. (2018). Data Descriptor: Tundra Landform and Vegetation Productivity Trend Maps for the Arctic Coastal Plain of Northern Alaska. Sci. Data.","DOI":"10.1038\/sdata.2018.58"},{"key":"ref_40","doi-asserted-by":"crossref","unstructured":"Billings, W.D., and Peterson, K.M. (1980). Vegetational Change and Ice-Wedge Polygons through the Thaw-Lake Cycle in Arctic Alaska. Arct. Alp. Res.","DOI":"10.2307\/1550492"},{"key":"ref_41","doi-asserted-by":"crossref","unstructured":"Chen, Y., Hu, F.S., and Lara, M.J. (2020). Divergent Shrub-Cover Responses Driven by Climate, Wildfire, and Permafrost Interactions in Arctic Tundra Ecosystems. Glob. Chang. Biol.","DOI":"10.1111\/gcb.15451"},{"key":"ref_42","unstructured":"Luedke, R., and Smith, R. (2020, July 05). Map Showing Distribution, Composition, and Age of Late Cenozoic Volcanic Centers in Alaska, Available online: https:\/\/ngmdb.usgs.gov\/Prodesc\/proddesc_8948.htm."},{"key":"ref_43","unstructured":"Strauss, J., Laboor, S., Fedorov, A.N., Fortier, D., Froese, D., Fuchs, M., Grosse, G., G\u00fcnther, F., Harden, J.W., and Hugelius, G. (2016). Database of Ice-Rich Yedoma Permafrost (IRYP). PANGAEA-Data Publ. Earth Environ. Sci."},{"key":"ref_44","doi-asserted-by":"crossref","unstructured":"West, J.J., and Plug, L.J. (2008). Time-Dependent Morphology of Thaw Lakes and Taliks in Deep and Shallow Ground Ice. J. Geophys. Res. Earth Surf.","DOI":"10.1029\/2006JF000696"},{"key":"ref_45","doi-asserted-by":"crossref","unstructured":"Roach, J.K., Griffith, B., and Verbyla, D. (2013). Landscape Influences on Climate-Related Lake Shrinkage at High Latitudes. Glob. Chang. Biol.","DOI":"10.1111\/gcb.12196"},{"key":"ref_46","doi-asserted-by":"crossref","unstructured":"Jones, B.M., and Arp, C.D. (2015). Observing a Catastrophic Thermokarst Lake Drainage in Northern Alaska. Permafr. Periglac. Process.","DOI":"10.1002\/ppp.1842"},{"key":"ref_47","doi-asserted-by":"crossref","unstructured":"Smith, L.C. (2005). Disappearing Arctic Lakes. Science.","DOI":"10.1126\/science.1108142"},{"key":"ref_48","unstructured":"Bergstedt, H., Jones, B., Farquharson, L.M., Gaglioti, B., Parsekian, A., Kanevskiy, M., Hinkel, K., Rangel, R., Ohara, N., and Breen, A. (2020, January 1\u20137). Towards Panarctic Mapping of Drained Lake Basins in Permafrost Regions. Proceedings of the American Geophysical Union Poster, Available online: https:\/\/agu.confex.com\/agu\/fm20\/meetingapp.cgi\/Paper\/669489."},{"key":"ref_49","doi-asserted-by":"crossref","unstructured":"Jorgenson, M.T., and Shur, Y. (2007). Evolution of Lakes and Basins in Northern Alaska and Discussion of the Thaw Lake Cycle. J. Geophys. Res. Earth Surf.","DOI":"10.1029\/2006JF000531"},{"key":"ref_50","doi-asserted-by":"crossref","unstructured":"Yoshikawa, K., and Hinzman, L.D. (2003). Shrinking Thermokarst Ponds and Groundwater Dynamics in Discontinuous Permafrost near Council, Alaska. Permafr. Periglac. Process.","DOI":"10.1002\/ppp.451"},{"key":"ref_51","doi-asserted-by":"crossref","unstructured":"Jorgenson, M.T., Marcot, B.G., Swanson, D.K., Jorgenson, J.C., and DeGange, A.R. (2015). Projected Changes in Diverse Ecosystems from Climate Warming and Biophysical Drivers in Northwest Alaska. Clim. Chang.","DOI":"10.1007\/s10584-014-1302-1"},{"key":"ref_52","doi-asserted-by":"crossref","unstructured":"Kokelj, S.V., Tunnicliffe, J., Lacelle, D., Lantz, T.C., Chin, K.S., and Fraser, R. (2015). Increased Precipitation Drives Mega Slump Development and Destabilization of Ice-Rich Permafrost Terrain, Northwestern Canada. Glob. Planet. Chang.","DOI":"10.1016\/j.gloplacha.2015.02.008"},{"key":"ref_53","doi-asserted-by":"crossref","unstructured":"Segal, R.A., Lantz, T.C., and Kokelj, S.V. (2016). Acceleration of Thaw Slump Activity in Glaciated Landscapes of the Western Canadian Arctic. Environ. Res. Lett.","DOI":"10.1088\/1748-9326\/11\/3\/034025"},{"key":"ref_54","doi-asserted-by":"crossref","unstructured":"Lewkowicz, A.G., and Way, R.G. (2019). Extremes of Summer Climate Trigger Thousands of Thermokarst Landslides in a High Arctic Environment. Nat. Commun.","DOI":"10.1038\/s41467-019-09314-7"},{"key":"ref_55","doi-asserted-by":"crossref","unstructured":"Walter Anthony, K., Daanen, R., Anthony, P., Schneider Von Deimling, T., Ping, C.L., Chanton, J.P., and Grosse, G. (2016). Methane Emissions Proportional to Permafrost Carbon Thawed in Arctic Lakes since the 1950s. Nat. Geosci.","DOI":"10.1038\/ngeo2795"},{"key":"ref_56","doi-asserted-by":"crossref","unstructured":"Walter, K.M., Zimov, S.A., Chanton, J.P., Verbyla, D., and Chapin, F.S. (2006). Methane Bubbling from Siberian Thaw Lakes as a Positive Feedback to Climate Warming. Nature.","DOI":"10.1038\/nature05040"},{"key":"ref_57","doi-asserted-by":"crossref","unstructured":"Zimov, S.A., Voropaev, Y.V., Semiletov, I.P., Davidov, S.P., Prosiannikov, S.F., Chapin, F.S., Chapin, M.C., Trumbore, S., and Tyler, S. (1997). North Siberian Lakes: A Methane Source Fueled by Pleistocene Carbon. Science.","DOI":"10.1126\/science.277.5327.800"},{"key":"ref_58","doi-asserted-by":"crossref","first-page":"99","DOI":"10.1038\/ngeo2578","article-title":"Climate-Sensitive Northern Lakes and Ponds Are Critical Components of Methane Release","volume":"9","author":"Wik","year":"2016","journal-title":"Nat. Geosci."},{"key":"ref_59","doi-asserted-by":"crossref","unstructured":"Lara, M.J., McGuire, A.D., Euskirchen, E.S., Genet, H., Yi, S., Rutter, R., Iversen, C., Sloan, V., and Wullschleger, S.D. (2020). Local-Scale Arctic Tundra Heterogeneity Affects Regional-Scale Carbon Dynamics. Nat. Commun.","DOI":"10.1038\/s41467-020-18768-z"},{"key":"ref_60","doi-asserted-by":"crossref","first-page":"75","DOI":"10.1016\/j.earscirev.2017.07.007","article-title":"Deep Yedoma Permafrost: A Synthesis of Depositional Characteristics and Carbon Vulnerability","volume":"172","author":"Strauss","year":"2017","journal-title":"Earth Sci. Rev."}],"container-title":["Remote Sensing"],"original-title":[],"language":"en","link":[{"URL":"https:\/\/www.mdpi.com\/2072-4292\/13\/5\/852\/pdf","content-type":"unspecified","content-version":"vor","intended-application":"similarity-checking"}],"deposited":{"date-parts":[[2025,10,11]],"date-time":"2025-10-11T05:28:15Z","timestamp":1760160495000},"score":1,"resource":{"primary":{"URL":"https:\/\/www.mdpi.com\/2072-4292\/13\/5\/852"}},"subtitle":[],"short-title":[],"issued":{"date-parts":[[2021,2,25]]},"references-count":60,"journal-issue":{"issue":"5","published-online":{"date-parts":[[2021,3]]}},"alternative-id":["rs13050852"],"URL":"https:\/\/doi.org\/10.3390\/rs13050852","relation":{},"ISSN":["2072-4292"],"issn-type":[{"value":"2072-4292","type":"electronic"}],"subject":[],"published":{"date-parts":[[2021,2,25]]}}}