Impact of measured and simulated tundra snowpack properties on heat transfer

Snowpack microstructure controls the transfer of heat to, and the temperature of, the underlying soils. In situ measurements of snow and soil properties from four field campaigns during two winters (March and November 2018, January and March 2019) were compared to an ensemble of CLM5.0 (Community La...

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Bibliographic Details
Published in:The Cryosphere
Main Authors: Dutch, Victoria, Rutter, Nick, Wake, Leanne, Sandells, Melody, Derksen, Chris, Walker, Brandener, Gosselin, Gabriel Hould, Sonnentag, Oliver, Essery, Richard, Kelly, Richard, Marsh, Philip, King, Joshua, Boike, Julia
Format: Article in Journal/Newspaper
Language:English
Published: Coperincus 2022
Subjects:
F800 Physical and Terrestrial Geographical and Environmental Sciences
Arctic
Canada
Sturm
Trail Valley Creek
Valley Creek
The Cryosphere
Tundra
Online Access:https://nrl.northumbria.ac.uk/id/eprint/50350/
https://doi.org/10.5194/tc-16-4201-2022
https://nrl.northumbria.ac.uk/id/eprint/50350/8/tc-16-4201-2022.pdf
https://nrl.northumbria.ac.uk/id/eprint/50350/1/Paper1_FINAL_clean.pdf
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Summary:Snowpack microstructure controls the transfer of heat to, and the temperature of, the underlying soils. In situ measurements of snow and soil properties from four field campaigns during two winters (March and November 2018, January and March 2019) were compared to an ensemble of CLM5.0 (Community Land Model) simulations, at Trail Valley Creek, Northwest 20 Territories, Canada. Snow MicroPenetrometer profiles allowed snowpack density and thermal conductivity to be derived at higher vertical resolution (1.25 mm) and a larger sample size (n = 1050) compared to traditional snowpit observations (3 cm vertical resolution; n = 115). Comparing measurements with simulations shows CLM overestimated snow thermal conductivity by a factor of 3, leading to a cold bias in wintertime soil temperatures (RMSE = 5.8 ℃). Two different approaches were taken to reduce this bias: alternative parameterisations of snow thermal conductivity and the application of a correction factor. All 25 the evaluated parameterisations of snow thermal conductivity improved simulations of wintertime soil temperatures, with that of Sturm et al. (1997) having the greatest impact (RMSE = 2.5 ℃). The required correction factor is strongly related to snow depth (R2 = 0.77, RMSE = 0.066) and thus differs between the two snow seasons, limiting the applicability of such an approach. Improving simulated snow properties and the corresponding heat flux is important, as wintertime soil temperatures are an important control on subnivean soil respiration, and hence impact Arctic winter carbon fluxes and budgets.

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