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多年冻土区的湖泊排水产生了具有高生物量和生产力的多样植物群落。

Lake Drainage in Permafrost Regions Produces Variable Plant Communities of High Biomass and Productivity.

作者信息

Loiko Sergey, Klimova Nina, Kuzmina Darya, Pokrovsky Oleg

机构信息

BIO-GEO-CLIM Laboratory, National Research Tomsk State University, Lenina St. 36, 634050 Tomsk, Russia.

Tomsk Oil and Gas Research and Design Institute (TomskNIPIneft), Prospect Mira 72, 634027 Tomsk, Russia.

出版信息

Plants (Basel). 2020 Jul 8;9(7):867. doi: 10.3390/plants9070867.

DOI:10.3390/plants9070867
PMID:32650600
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7411715/
Abstract

Climate warming, increased precipitation, and permafrost thaw in the Arctic are accompanied by an increase in the frequency of full or partial drainage of thermokarst lakes. After lake drainage, highly productive plant communities on nutrient-rich sediments may develop, thus increasing the influencing greening trends of Arctic tundra. However, the magnitude and extent of this process remain poorly understood. Here we characterized plant succession and productivity along a chronosequence of eight drained thermokarst lakes (khasyreys), located in the low-Arctic tundra of the Western Siberian Lowland (WSL), the largest permafrost peatland in the world. Based on a combination of satellite imagery, archive mapping, and radiocarbon dating, we distinguished early (<50 years), mid (50-200 years), and late (200-2000 years) ecosystem stages depending on the age of drainage. In 48 sites within the different aged khasyreys, we measured plant phytomass and productivity, satellite-derived NDVImax, species composition, soil chemistry including nutrients, and plant elementary composition. The annual aboveground net primary productivity of the early and mid khasyrey ranged from 1134 and 660 g·m·y, which is two to nine times higher than that of the surrounding tundra. Late stages exhibited three to five times lower plant productivity and these ecosystems were distinctly different from early and mid-stages in terms of peat thickness and pools of soil nitrogen and potassium. We conclude that the main driving factor of the vegetation succession in the khasyreys is the accumulation of peat and the permafrost aggradation. The soil nutrient depletion occurs simultaneously with a decrease in the thickness of the active layer and an increase in the thickness of the peat. The early and mid khasyreys may provide a substantial contribution to the observed greening of the WSL low-Arctic tundra.

摘要

北极地区的气候变暖、降水增加和永久冻土融化,伴随着热喀斯特湖完全或部分排水频率的增加。湖泊排水后,营养丰富沉积物上高产的植物群落可能会发展起来,从而增强北极苔原的绿化趋势。然而,这一过程的规模和程度仍知之甚少。在此,我们对位于西西伯利亚低地(WSL)低北极苔原的八个排水热喀斯特湖(哈西雷湖)的时间序列中的植物演替和生产力进行了特征描述,西西伯利亚低地是世界上最大的永久冻土泥炭地。基于卫星图像、档案地图和放射性碳测年的结合,我们根据排水时间区分了早期(<50年)、中期(50 - 200年)和晚期(200 - 2000年)的生态系统阶段。在不同年代的哈西雷湖中的48个地点,我们测量了植物生物量和生产力、卫星衍生的最大归一化植被指数(NDVImax)、物种组成、包括养分在内的土壤化学性质以及植物元素组成。早期和中期哈西雷湖的年地上净初级生产力范围为1134和660 g·m⁻²·y⁻¹,比周围苔原高两到九倍。晚期阶段的植物生产力低三到五倍,并且这些生态系统在泥炭厚度以及土壤氮和钾库方面与早期和中期明显不同。我们得出结论,哈西雷湖植被演替的主要驱动因素是泥炭的积累和永久冻土的加厚。土壤养分消耗与活动层厚度的减少和泥炭厚度的增加同时发生。早期和中期的哈西雷湖可能对观察到的WSL低北极苔原的绿化做出了重大贡献。

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本文引用的文献

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2
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Nat Commun. 2019 Jan 16;10(1):264. doi: 10.1038/s41467-018-08240-4.
3
Recent dynamics of hydro-ecosystems in thermokarst depressions in Central Siberia from satellite and in situ observations: Importance for agriculture and human life.近西伯利亚中部热喀斯特洼地水-生态系统的卫星和原位观测动态:对农业和人类生活的重要性。
Biogeochemistry. 2022 Mar;158(2):215-232. doi: 10.1007/s10533-022-00895-y. Epub 2022 Feb 21.
4
Vulnerability of the Ancient Peat Plateaus in Western Siberia.西西伯利亚古代泥炭高原的脆弱性
Plants (Basel). 2021 Dec 19;10(12):2813. doi: 10.3390/plants10122813.
Sci Total Environ. 2018 Feb 15;615:1290-1304. doi: 10.1016/j.scitotenv.2017.09.059. Epub 2017 Oct 17.
4
Permafrost thaw and climate warming may decrease the CO, carbon, and metal concentration in peat soil waters of the Western Siberia Lowland.永冻层解冻和气候变暖可能会降低西西伯利亚低地泥炭土壤水中的 CO、碳和金属浓度。
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5
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6
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7
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9
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10
Endangered plants persist under phosphorus limitation.濒危植物在磷限制条件下仍能存活。
Nature. 2005 Sep 22;437(7058):547-50. doi: 10.1038/nature03950.