Arctic permafrost landscapes in transition: towards an integrated Earth system approach

Warwick F Vincent,Mickaël Lemay,Michel Allard

doi:10.1139/as-2016-0027

Warwick F Vincent, Mickaël Lemay + Show 1 more

Open Access

https://doi.org/10.1139/as-2016-0027

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Journal: Arctic Science	Publication Date: Apr 21, 2017
Citations: 70	License type: cc-by

Affiliation: Center for Northern Studies, Université Laval

Abstract

Permafrost science and engineering are of vital importance for northern development and climate adaptation given that buildings, roads, and other infrastructure in many parts of the Arctic depend on permafrost stability. Permafrost also has wide-ranging effects on other features of the Arctic environment including geomorphology, biogeochemical fluxes, tundra plant and animal ecology, and the functioning of lake, river, and coastal marine ecosystems. This review presents an Earth system perspective on permafrost landscapes as an approach towards integration across disciplines. The permafrost system can be described by a three-layer conceptual model, with an upper buffer layer that contains vegetation or infrastructure. Snow and liquid water strongly affect the thermal properties and stability of these layers and their associated interfaces, resulting in critical times and places for accelerated degradation of permafrost and for exchanges of mass and heat with the hydrosphere and atmosphere. Northern permafrost landscapes are now in rapid transition as a result of climate warming and socioeconomic development, which is affecting their ability to provide geosystem and ecosystem services. The Earth system approach provides a framework for identifying linkages, thresholds, and feedbacks among system components, including human systems, and for the development of management strategies to cope with permafrost change.

Highlights

Introduction “M. von Buch, in an address which he read to the academy of Berlin in the year 1825, distinctly expressed it as a matter of doubt, whether in a district covered with wood the ground can be in a frozen state at such great a depth as the first excavation at Yakutsk had reached, namely 91 English feet” (Von Baer 1838)
The early reports of ‘permanently frozen ground’ in Siberia were initially greeted with some degree of skepticism, but by the mid-19th century, borehole temperature measurements had been made to great depth and had unequivocally shown that permafrost at Yakutsk extended to well below 100 m
At Prudhoe Bay, Alaska, for example, thermal modelling indicates that permafrost >600 m in saturated mineral soils would https://mc06.manuscriptcentral.com/asopen-pubs have taken hundreds of thousands of years to form, through several ice ages (Lunardini 1995), while in some subarctic regions the current permafrost may be a legacy of the Little Ice Age some 300 years ago (Bhiry et al 2011)

Summary

Arctic Science

Arctic permafrost landscapes in transition: Towards an integrated Earth system approach. Journal: Arctic Science Manuscript ID AS-2016-0027.R1 Manuscript Type: Review Date Submitted by the Author: 19-Apr-2017 Complete List of Authors: Vincent, Warwick; Université Laval, Biologie & Centre d'études nordiques. Mickaël; Université Laval, Centre d'études nordiques Allard, Michel; Université Laval, Géographie & Centre d'études nordiques Keyword: climate change, permafrost, thermokarst, Arctic, infrastructure https://mc06.manuscriptcentral.com/asopen-pubs. Département de Biologie, Takuvik Joint International Laboratory, and Centre d’études nordiques (CEN), Université Laval, Québec, QC G1V 0A6, Canada. Mickaël Lemay, Centre d’études nordiques (CEN), Université Laval, Québec, QC G1V 0A6, Canada. Michel Allard, Département de Géographie, Takuvik Joint International Laboratory, and Centre d’études nordiques (CEN), Université Laval, Québec QC G1V 0A6, Canada

Conclusions

Findings

Water bodies