Vulnerability of permafrost carbon to global warming. Part II: Sensitivity of permafrost carbon stock to global warming

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Dimitry V. Khvorostyanov
  • P. Ciais
  • G. Krinner
  • S. A. Zimov
  • Ch Corradi
  • G. Guggenberger

External Research Organisations

  • Universita della Tuscia
  • Martin Luther University Halle-Wittenberg
  • Laboratoire des sciences du climat et de l'environnement
  • Russian Academy of Sciences (RAS)
  • Universite Joseph Fourier (UJF)
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Details

Original languageEnglish
Pages (from-to)265-275
Number of pages11
JournalTellus, Series B: Chemical and Physical Meteorology
Volume60 B
Issue number2
Publication statusPublished - 2008
Externally publishedYes

Abstract

In the companion paper (Part I), we presented a model of permafrost carbon cycle to study the sensitivity of frozen carbon stocks to future climate warming. The mobilization of deep carbon stock of the frozen Pleistocene soil in the case of rapid stepwise increase of atmospheric temperature was considered. In this work, we adapted the model to be used also for floodplain tundra sites and to account for the processes in the soil active layer. The new processes taken into account are litter input and decomposition, plant-mediated transport of methane, and leaching of exudates from plant roots. The SRES-A2 transient climate warming scenario of the IPSL CM4 climate model is used to study the carbon fluxes from the carbon-rich Pleistocene soil with seasonal active-layer carbon cycling on top of it. For a point to the southwest from the western branch of Yedoma Ice Complex, where the climate warming is strong enough to trigger self-sustainable decomposition processes, about 256 kgC m-2, or 70% of the initial soil carbon stock under present-day climate conditions, are emitted to the atmosphere in about 120 yr, including 20 kgC m-2 released as methane. The total average flux of CO2 and methane emissions to the atmosphere during this time is of 2.1 kgC m-2 yr-1. Within the Yedoma, whose most part of the territory remains relatively cold, the emissions are much smaller: 0.2 kgC m-2 yr-1 between 2050 and 2100 for Yakutsk area. In a test case with saturated upper-soil meter, when the runoff is insufficient to evacuate the meltwater, 0.05 kgCH4 m-2 yr-1 on average are emitted as methane during 250 yr starting from 2050. The latter can translate to the upper bound of 1 GtC yr-1 in CO2 equivalent from the 1 million km2 area of the Yedoma.

ASJC Scopus subject areas

Sustainable Development Goals

Cite this

Vulnerability of permafrost carbon to global warming. Part II: Sensitivity of permafrost carbon stock to global warming. / Khvorostyanov, Dimitry V.; Ciais, P.; Krinner, G. et al.
In: Tellus, Series B: Chemical and Physical Meteorology, Vol. 60 B, No. 2, 2008, p. 265-275.

Research output: Contribution to journalArticleResearchpeer review

Khvorostyanov DV, Ciais P, Krinner G, Zimov SA, Corradi C, Guggenberger G. Vulnerability of permafrost carbon to global warming. Part II: Sensitivity of permafrost carbon stock to global warming. Tellus, Series B: Chemical and Physical Meteorology. 2008;60 B(2):265-275. doi: 10.1111/j.1600-0889.2007.00336.x
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title = "Vulnerability of permafrost carbon to global warming.: Part II: Sensitivity of permafrost carbon stock to global warming",
abstract = "In the companion paper (Part I), we presented a model of permafrost carbon cycle to study the sensitivity of frozen carbon stocks to future climate warming. The mobilization of deep carbon stock of the frozen Pleistocene soil in the case of rapid stepwise increase of atmospheric temperature was considered. In this work, we adapted the model to be used also for floodplain tundra sites and to account for the processes in the soil active layer. The new processes taken into account are litter input and decomposition, plant-mediated transport of methane, and leaching of exudates from plant roots. The SRES-A2 transient climate warming scenario of the IPSL CM4 climate model is used to study the carbon fluxes from the carbon-rich Pleistocene soil with seasonal active-layer carbon cycling on top of it. For a point to the southwest from the western branch of Yedoma Ice Complex, where the climate warming is strong enough to trigger self-sustainable decomposition processes, about 256 kgC m-2, or 70% of the initial soil carbon stock under present-day climate conditions, are emitted to the atmosphere in about 120 yr, including 20 kgC m-2 released as methane. The total average flux of CO2 and methane emissions to the atmosphere during this time is of 2.1 kgC m-2 yr-1. Within the Yedoma, whose most part of the territory remains relatively cold, the emissions are much smaller: 0.2 kgC m-2 yr-1 between 2050 and 2100 for Yakutsk area. In a test case with saturated upper-soil meter, when the runoff is insufficient to evacuate the meltwater, 0.05 kgCH4 m-2 yr-1 on average are emitted as methane during 250 yr starting from 2050. The latter can translate to the upper bound of 1 GtC yr-1 in CO2 equivalent from the 1 million km2 area of the Yedoma.",
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AU - Khvorostyanov, Dimitry V.

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