气候变化领域集成服务门户(CCPortal): Recent degradation of interior Alaska permafrost mapped with ground surveys, geophysics, deep drilling, and repeat airborne lidar

CCPortal

DOI	10.5194/tc-15-3555-2021
	Recent degradation of interior Alaska permafrost mapped with ground surveys, geophysics, deep drilling, and repeat airborne lidar
	Douglas T.A.; Hiemstra C.A.; Anderson J.E.; Barbato R.A.; Bjella K.L.; Deeb E.J.; Gelvin A.B.; Nelsen P.E.; Newman S.D.; Saari S.P.; Wagner A.M.
发表日期	2021
ISSN	19940416
起始页码	3555
结束页码	3575
卷号	15 期号:8
英文摘要	Permafrost underlies one-quarter of the Northern Hemisphere but is at increasing risk of thaw from climate warming. Recent studies across the Arctic have identified areas of rapid permafrost degradation from both top-down and lateral thaw. Of particular concern is thawing syngenetic "yedoma"permafrost which is ice-rich and has a high carbon content. This type of permafrost is common in the region around Fairbanks, Alaska, and across central Alaska expanding westward to the Seward Peninsula. A major knowledge gap is relating belowground measurements of seasonal thaw, permafrost characteristics, and residual thaw layer development with aboveground ecotype properties and thermokarst expansion that can readily quantify vegetation cover and track surface elevation changes over time. This study was conducted from 2013 to 2020 along four 400 to 500ĝ€¯m long transects near Fairbanks, Alaska. Repeat active layer depths, near-surface permafrost temperature measurements, electrical resistivity tomography (ERT), deep (>ĝ€¯5ĝ€¯m) boreholes, and repeat airborne light detection and ranging (lidar) were used to measure top-down permafrost thaw and map thermokarst development at the sites. Our study confirms previous work using ERT to map surface thawed zones; however, our deep boreholes confirm the boundaries between frozen and thawed zones that are needed to model top-down, lateral, and bottom-up thaw. At disturbed sites seasonal thaw increased up to 25ĝ€¯% between mid-August and early October and suggests measurements to evaluate active layer depth must be made as late in the fall season as possible because the projected increase in the summer season of just a few weeks could lead to significant additional thaw. At our sites, tussock tundra and spruce forest are associated with the lowest mean annual near-surface permafrost temperatures while mixed-forest ecotypes are the warmest and exhibit the highest degree of recent temperature warming and thaw degradation. Thermokarst features, residual thaw layers, and taliks have been identified at all sites. Our measurements, when combined with longer-Term records from yedoma across the 500ĝ€¯000ĝ€¯km2 area of central Alaska, show widespread near-surface permafrost thaw since 2010. Projecting our thaw depth increases, by ecotype, across the yedoma domain, we calculate a first-order estimate that 0.44ĝ€¯Pg of organic carbon in permafrost soil has thawed over the past 7 years, which, for perspective, is an amount of carbon nearly equal to the yearly CO2 emissions of Australia. Since the yedoma permafrost and the variety of ecotypes at our sites represent much of the Arctic and subarctic land cover, this study shows remote sensing measurements, top-down and bottom-up thermal modeling, and ground-based surveys can be used predictively to identify areas of the highest risk for permafrost thaw from projected future climate warming. © 2021 Copernicus GmbH. All rights reserved.
语种	英语
来源期刊	Cryosphere
文献类型	期刊论文
条目标识符	http://gcip.llas.ac.cn/handle/2XKMVOVA/202299
作者单位	U.S. Army Cold Regions Research and Engineering Laboratory, 9th Avenue, Fort Wainwright, AK 99709, United States; U.S. Army Geospatial Research Laboratory, Corbin Field Station, 15315 Magnetic Lane, Woodford, VA 22580, United States; U.S. Army Cold Regions Research and Engineering Laboratory, 72 Lyme Road, Hanover, NH 03755, United States; US Department of Agriculture, Forest Service, Geospatial Management Office, Salt Lake City, UTaa 84138, United States
推荐引用方式 GB/T 7714	Douglas T.A.,Hiemstra C.A.,Anderson J.E.,et al. Recent degradation of interior Alaska permafrost mapped with ground surveys, geophysics, deep drilling, and repeat airborne lidar[J],2021,15(8).
APA	Douglas T.A..,Hiemstra C.A..,Anderson J.E..,Barbato R.A..,Bjella K.L..,...&Wagner A.M..(2021).Recent degradation of interior Alaska permafrost mapped with ground surveys, geophysics, deep drilling, and repeat airborne lidar.Cryosphere,15(8).
MLA	Douglas T.A.,et al."Recent degradation of interior Alaska permafrost mapped with ground surveys, geophysics, deep drilling, and repeat airborne lidar".Cryosphere 15.8(2021).