4.7 Article

Tree ring-based reconstruction of the long-term influence of wildfires on permafrost active layer dynamics in Central Siberia

期刊

SCIENCE OF THE TOTAL ENVIRONMENT
卷 652, 期 -, 页码 314-319

出版社

ELSEVIER
DOI: 10.1016/j.scitotenv.2018.10.124

关键词

Boreal forest; Ecological interaction; Ecosystem response; Seasonally thawing soil layer; Sphagnum; Larix gmelinii

资金

  1. Russian Science Foundation [RSF 18-14-00072]
  2. Ministry of Education and Science of the Russian Federation [5.3508.2017/4.6]
  3. Russian Foundation for Basic Research [RFBR 18-05-60203]
  4. Russian Science Foundation [18-14-00072] Funding Source: Russian Science Foundation

向作者/读者索取更多资源

Although it has been recognized that rising temperatures and shifts in the hydrological cycle affect the depth of the seasonally thawing upper permafrost stratum, it remains unclear to what extent the frequency and intensity of wildfires, and subsequent changes in vegetation cover, influence the soil active layer on different spatiotemporal scales. Here, we use ring width measurements of the subterranean stem part of 15 larch trees from a Sphagnum bog site in Central Siberia to reconstruct long-term changes in the thickness of the active layer since the last wildfire occurred in 1899. Our approach reveals a three-step feedback loop between above- and belowground ecosystem components. After all vegetation is burned, direct atmospheric heat penetration over the first similar to 20 years caused thawing of the upper permafrost stratum. The slow recovery of the insulating ground vegetation reverses the process and initiates a gradual decrease of the active layer thickness. Due to the continuous spreading and thickening of the peat layer during the last decades, the upper permafrost horizon has increased by 0.52 cm/year. This study demonstrates the strength of annually resolved and absolutely dated tree-ring series to reconstruct the effects of historical wildfires on the functioning and productivity of boreal forest ecosystems at multi-decadal to centennial time-scale. In so doing, we show how complex interactions of above- and belowground components translate into successive changes in the active permafrost stratum. Our results are particularly relevant for improving long-term estimates of the global carbon cycle that strongly depends on the source and sink behavior of the boreal forest zone. (C) 2018 Elsevier B.V. All rights reserved.

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