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Hydrologic-land surface modelling of the Canadian sporadic-discontinuous permafrost: initialization and uncertainty propagation
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  • Mohamed Abdelhamed,
  • Mohamed Elshamy,
  • Howard Wheater,
  • Saman Razavi
Mohamed Abdelhamed
University of Saskatchewan

Corresponding Author:mohamed.abdelhamed@usask.ca

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Mohamed Elshamy
University of Saskatchewan
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Howard Wheater
University of Saskatchewan
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Saman Razavi
University of Saskatchewan
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Abstract

Permafrost thaw has been observed in recent decades in the Northern Hemisphere and is expected to accelerate with continued global warming. Predicting the future of permafrost requires proper representation of the interrelated surface/subsurface thermal and hydrologic regimes. Land surface models (LSMs) are well suited for such predictions, as they couple heat and water interactions across soil-vegetation-atmosphere interfaces and can be applied over large scales. LSMs, however, are challenged by the long-term thermal and hydraulic memories of permafrost and the paucity of historical records to represent permafrost dynamics under transient climate conditions. In this study, we address the challenge of model initialization by characterizing the impact of initial climate conditions and initial soil frozen and liquid water contents on the simulation length required to reach equilibrium. Further, we quantify how the uncertainty in model initialization propagates to simulated permafrost dynamics. Modelling experiments are conducted with the Modélisation Environmentale Communautaire – Surface and Hydrology (MESH) framework and its embedded Canadian Land Surface Scheme (CLASS). The study area is in the Liard River basin in the Northwest Territories of Canada with sporadic and discontinuous regions. Results show that uncertainty in model initialization controls various attributes of simulated permafrost, especially the active layer thickness, which could change by 0.5-1.5m depending on the initial condition chosen. The least number of spin-up cycles is achieved with near field capacity condition, but the number of cycles varies depending on the spin-up year climate. We advise an extended spin-up of 200-1000 cycles to ensure proper model initialization under different climatic conditions and initial soil moisture contents.
23 Apr 2021Submitted to Hydrological Processes
24 Apr 2021Submission Checks Completed
24 Apr 2021Assigned to Editor
26 Apr 2021Reviewer(s) Assigned
22 Jul 2021Review(s) Completed, Editorial Evaluation Pending
24 Jul 2021Editorial Decision: Revise Major
27 Oct 20211st Revision Received
28 Oct 2021Submission Checks Completed
28 Oct 2021Assigned to Editor
28 Oct 2021Reviewer(s) Assigned
26 Nov 2021Review(s) Completed, Editorial Evaluation Pending
03 Dec 2021Editorial Decision: Revise Minor
15 Dec 20212nd Revision Received
16 Dec 2021Submission Checks Completed
16 Dec 2021Assigned to Editor
16 Dec 2021Reviewer(s) Assigned
16 Dec 2021Review(s) Completed, Editorial Evaluation Pending
21 Jan 2022Editorial Decision: Revise Minor
27 Jan 20223rd Revision Received
27 Jan 2022Submission Checks Completed
27 Jan 2022Assigned to Editor
27 Jan 2022Reviewer(s) Assigned
27 Jan 2022Review(s) Completed, Editorial Evaluation Pending
29 Jan 2022Editorial Decision: Accept
Mar 2022Published in Hydrological Processes volume 36 issue 3. 10.1002/hyp.14509