Arctic, Antarctic, and Alpine Research (Dec 2022)

Abrupt permafrost thaw accelerates carbon dioxide and methane release at a tussock tundra site

  • Heidi Rodenhizer,
  • Fay Belshe,
  • Gerardo Celis,
  • Justin Ledman,
  • Marguerite Mauritz,
  • Scott Goetz,
  • Temuulen Sankey,
  • Edward A.G. Schuur

DOI
https://doi.org/10.1080/15230430.2022.2118639
Journal volume & issue
Vol. 54, no. 1
pp. 443 – 464

Abstract

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Abrupt thaw could cause permafrost ecosystems to release more carbon than is predicted from gradual thaw alone. However, thermokarst feature mapping is limited in scope, and observed responses of carbon fluxes to abrupt thaw are variable. We developed a thermokarst detection algorithm that identifies thermokarst features from a single elevation dataset with 71.5 percent accuracy and applied it in Healy, Alaska. Additionally, we investigated the landscape-level variation in carbon dioxide and methane fluxes by extent of abrupt thaw using eddy covariance. Seven percent of the site was classified as thermokarst. Water tracks were the most extensive form of thermokarst, although small pits were much more numerous. Abrupt thaw was positively correlated with carbon uptake during the growing season, when increases in gross primary productivity outpaced increases in ecosystem respiration in vegetation-dense water tracks. However, this was outweighed by higher carbon release in thermokarst features during the nongrowing season. Additionally, abrupt thaw was positively correlated with methane production nearly year-round. Our findings support the hypothesis that abrupt thaw of permafrost carbon will contribute to the permafrost climate feedback above and beyond that associated with gradual thaw and highlights the need to map thermokarst and incorporate abrupt thaw into Earth System Models.

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