Characterizing Dissolved Organic Matter and Other Water-Soluble Compounds in Ground Ice of the Russian Arctic: A Focus on Ground Ice Classification within the Carbon Cycle Context

Petr Semenov, A. Pismeniuk, Anna Kil, Elizaveta Shatrova, Natalia Belova, Petr Gromov, Sergei Malyshev, Wei He, Anastasiia Lodochnikova, I. Tarasevich, Irina Streletskaya, Marina Leibman
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Abstract

Climate-induced changes contribute to the thawing of ice-rich permafrost in the Arctic, which leads to the release of large amounts of organic carbon into the atmosphere in the form of greenhouse gases, mainly carbon dioxide and methane. Ground ice constitutes a considerable volume of the cryogenically sequestered labile dissolved organic carbon (DOC) subjected to fast mineralization upon thawing. In this work, we collected a unique geochemical database of the ground and glacier ice comprising the samples from various geographic locations in the Russian Arctic characterized by a variety of key parameters, including ion composition, carbon-bearing gases (methane and carbon dioxide), bulk biogeochemical indicators, and fluorescent dissolved organic matter (DOM) fractions. Our results show that interaction with solid material—such as sediments, detritus, and vegetation—is likely the overriding process in enrichment of the ground ice in all the dissolved compounds. Terrigenous humic-like dissolved organic matter was predominant in all the analyzed ice samples except for glacier ice from Bolshevik Island (the Severnaya Zemlya archipelago) and pure (with low sediment content) tabular ground ice from western Yamal. The labile protein-like DOM showed no correlation to humic components and was probably linked to microbial abundance in the ground ice. The sum of the fluorophores deconvoluted by PARAFAC strongly correlates to DOC, which proves the potential of using this approach for differentiation of bulk DOC into fractions with various origins and biogeochemical behaviors. The pure tabular ground ice samples exhibit the highest rate of fresh easily degradable DOM in the bulk DOC, which may be responsible for the amplification of permafrost organic matter decomposition upon thawing.
俄罗斯北极地区地冰中溶解有机物和其他水溶性化合物的特征:关注碳循环背景下的地冰分类
气候引起的变化导致北极地区富含冰的永久冻土融化,从而导致大量有机碳以温室气体(主要是二氧化碳和甲烷)的形式释放到大气中。地表冰在低温封存的可溶性有机碳(DOC)中占有相当大的体积,在解冻时会快速矿化。在这项工作中,我们收集了一个独特的地冰和冰川冰地球化学数据库,其中包括来自俄罗斯北极地区不同地理位置的样本,这些样本具有各种关键参数,包括离子成分、含碳气体(甲烷和二氧化碳)、大量生物地球化学指标以及荧光溶解有机物(DOM)组分。我们的研究结果表明,与固体物质(如沉积物、残渣和植被)的相互作用可能是地冰富集所有溶解化合物的主要过程。除了来自 Bolshevik 岛(塞维利亚泽姆利亚群岛)的冰川冰和来自亚马尔西部的纯净(沉积物含量低)表层地冰外,在所有分析过的冰样本中,土生腐殖质类溶解有机物都占主导地位。可溶性蛋白样 DOM 与腐殖质成分没有相关性,可能与地冰中微生物的数量有关。PARAFAC 分卷的荧光团总和与 DOC 密切相关,这证明了使用这种方法将大量 DOC 区分为具有不同来源和生物地球化学行为的部分的潜力。在大体积 DOC 中,纯表层地冰样本中新鲜易降解 DOM 的比率最高,这可能是解冻后永久冻土有机物分解加剧的原因。
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