末次冰消期热喀斯特湖作为大气甲烷的一个来源

Thermokarst lakes as a source of atmospheric CH4 during the last deglaciation.

作者信息

Walter K M, Edwards M E, Grosse G, Zimov S A, Chapin F S

机构信息

Water and Environmental Research Center, University of Alaska, Fairbanks, AK 99775, USA.

出版信息

Science. 2007 Oct 26;318(5850):633-6. doi: 10.1126/science.1142924.

DOI:10.1126/science.1142924

PMID:17962561

Abstract

Polar ice-core records suggest that an arctic or boreal source was responsible for more than 30% of the large increase in global atmospheric methane (CH4) concentration during deglacial climate warming; however, specific sources of that CH4 are still debated. Here we present an estimate of past CH4 flux during deglaciation from bubbling from thermokarst (thaw) lakes. Based on high rates of CH4 bubbling from contemporary arctic thermokarst lakes, high CH4 production potentials of organic matter from Pleistocene-aged frozen sediments, and estimates of the changing extent of these deposits as thermokarst lakes developed during deglaciation, we find that CH4 bubbling from newly forming thermokarst lakes comprised 33 to 87% of the high-latitude increase in atmospheric methane concentration and, in turn, contributed to the climate warming at the Pleistocene-Holocene transition.

摘要

极地冰芯记录表明，在冰消期气候变暖期间，全球大气甲烷（CH₄）浓度大幅增加，其中超过30%来自北极或北方地区的排放源；然而，这些甲烷的具体来源仍存在争议。在此，我们给出了冰消期期间热喀斯特（融化）湖冒泡产生的甲烷通量的估算值。基于当代北极热喀斯特湖甲烷冒泡的高速率、更新世时期冻结沉积物中有机物的高甲烷生产潜力，以及随着冰消期热喀斯特湖的形成这些沉积物范围变化的估算，我们发现新形成的热喀斯特湖冒泡产生的甲烷占高纬度地区大气甲烷浓度增加量的33%至87%，进而对更新世 - 全新世过渡时期的气候变暖起到了推动作用。

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末次冰消期热喀斯特湖作为大气甲烷的一个来源

Thermokarst lakes as a source of atmospheric CH4 during the last deglaciation.

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