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Patterns of permafrost formation and degradation in relation to climate and ecosystems

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  • Y. L. Shur
  • M. T. Jorgenson

Abstract

We develop a permafrost classification system to describe the complex interaction of climatic and ecological processes in permafrost formation and degradation that differentiates five patterns of formation: ‘climate‐driven’; ‘climate‐driven, ecosystem‐modified’; ‘climate‐driven, ecosystem‐protected’; ‘ecosystem‐driven’; and ‘ecosystem‐protected’ permafrost. Climate‐driven permafrost develops in the continuous permafrost zone, where permafrost forms immediately after the surface is exposed to the atmosphere and even under shallow water. Climate‐driven, ecosystem‐modified permafrost occurs in the continuous permafrost zone when vegetation succession and organic‐matter accumulation lead to development of an ice‐rich layer at the top of the permafrost. During warming climates, permafrost that has formed as climate‐driven can occur in the discontinuous permafrost zone, where it can persist for a long time as ecosystem‐protected. Climate‐driven, ecosystem protected permafrost, and its associated ground ice, cannot re‐establish in the discontinuous zone once degraded, although the near surface can recover as ecosystem‐driven permafrost. Ecosystem‐driven permafrost forms in the discontinuous permafrost zone in poorly drained, low‐lying and north‐facing landscape conditions, and under strong ecosystem influence. Finally, ecosystem‐protected permafrost persists as sporadic patches under warmer climates, but cannot be re‐established after disturbance. These distinctions are important because the various types react differently to climate change and surface disturbances. For example, climate‐driven, ecosystem‐modified permafrost can experience thermokarst even under cold conditions because of its ice‐rich layer formed during ecosystem development, and ecosystem‐driven permafrost is unlikely to recover after disturbance, such as fire, if there is sufficient climate warming. Copyright © 2007 John Wiley & Sons, Ltd.

Suggested Citation

  • Y. L. Shur & M. T. Jorgenson, 2007. "Patterns of permafrost formation and degradation in relation to climate and ecosystems," Permafrost and Periglacial Processes, John Wiley & Sons, vol. 18(1), pages 7-19, January.
    • Handle: RePEc:wly:perpro:v:18:y:2007:i:1:p:7-19
    DOI: 10.1002/ppp.582
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    Citations

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    Cited by:

    1. Jason R. Paul & Steven V. Kokelj & Jennifer L. Baltzer, 2021. "Spatial and stratigraphic variation of near‐surface ground ice in discontinuous permafrost of the taiga shield," Permafrost and Periglacial Processes, John Wiley & Sons, vol. 32(1), pages 3-18, January.
    2. Eva Stephani & Jeremiah Drage & Duane Miller & Benjamin M. Jones & Mikhail Kanevskiy, 2020. "Taliks, cryopegs, and permafrost dynamics related to channel migration, Colville River Delta, Alaska," Permafrost and Periglacial Processes, John Wiley & Sons, vol. 31(2), pages 239-254, April.
    3. Dongyu Yang & Daqing Zhan & Miao Li & Shuying Zang, 2023. "Factors Influencing the Spatiotemporal Changes of Permafrost in Northeast China from 1982 to 2020," Land, MDPI, vol. 12(2), pages 1-22, January.
    4. Wei Shan & Lisha Qiu & Ying Guo & Chengcheng Zhang & Zhichao Xu & Shuai Liu, 2022. "Spatiotemporal Distribution Characteristics of Fire Scars Further Prove the Correlation between Permafrost Swamp Wildfires and Methane Geological Emissions," Sustainability, MDPI, vol. 14(22), pages 1-20, November.
    5. Roman Desyatkin & Matrena Okoneshnikova & Alexandra Ivanova & Maya Nikolaeva & Nikolay Filippov & Alexey Desyatkin, 2022. "Dynamics of Vegetation and Soil Cover of Pyrogenically Disturbed Areas of the Northern Taiga under Conditions of Thermokarst Development and Climate Warming," Land, MDPI, vol. 11(9), pages 1-21, September.
    6. Mohamed Abdouli & Sami Hammami, 2020. "Economic Growth, Environment, FDI Inflows, and Financial Development in Middle East Countries: Fresh Evidence from Simultaneous Equation Models," Journal of the Knowledge Economy, Springer;Portland International Center for Management of Engineering and Technology (PICMET), vol. 11(2), pages 479-511, June.
    7. Felix C. Nwaishi & Matthew Q. Morison & Brandon Van Huizen & Myroslava Khomik & Richard M. Petrone & Merrin L. Macrae, 2020. "Growing season CO2 exchange and evapotranspiration dynamics among thawing and intact permafrost landforms in the Western Hudson Bay lowlands," Permafrost and Periglacial Processes, John Wiley & Sons, vol. 31(4), pages 509-523, October.
    8. Georgii A. Alexandrov & Veronika A. Ginzburg & Gregory E. Insarov & Anna A. Romanovskaya, 2021. "CMIP6 model projections leave no room for permafrost to persist in Western Siberia under the SSP5-8.5 scenario," Climatic Change, Springer, vol. 169(3), pages 1-11, December.
    9. Jean E. Holloway & Antoni G. Lewkowicz & Thomas A. Douglas & Xiaoying Li & Merritt R. Turetsky & Jennifer L. Baltzer & Huijun Jin, 2020. "Impact of wildfire on permafrost landscapes: A review of recent advances and future prospects," Permafrost and Periglacial Processes, John Wiley & Sons, vol. 31(3), pages 371-382, July.
    10. E. Schuur & B. Abbott & W. Bowden & V. Brovkin & P. Camill & J. Canadell & J. Chanton & F. Chapin & T. Christensen & P. Ciais & B. Crosby & C. Czimczik & G. Grosse & J. Harden & D. Hayes & G. Hugelius, 2013. "Expert assessment of vulnerability of permafrost carbon to climate change," Climatic Change, Springer, vol. 119(2), pages 359-374, July.
    11. Feng Cheng & Carmala Garzione & Xiangzhong Li & Ulrich Salzmann & Florian Schwarz & Alan M. Haywood & Julia Tindall & Junsheng Nie & Lin Li & Lin Wang & Benjamin W. Abbott & Ben Elliott & Weiguo Liu &, 2022. "Alpine permafrost could account for a quarter of thawed carbon based on Plio-Pleistocene paleoclimate analogue," Nature Communications, Nature, vol. 13(1), pages 1-12, December.

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