Brief communication: Monitoring snow depth using small, cheap, and easy-to-deploy snow–ground interface temperature sensors

Claire L. Bachand; Chen Wang; Baptiste Dafflon; Lauren N. Thomas; Ian Shirley; Sarah Maebius; Colleen M. Iversen; Katrina E. Bennett

doi:10.5194/tc-19-393-2025

Brief communication: Monitoring snow depth using small, cheap, and easy-to-deploy snow–ground interface temperature sensors

Claire L. Bachand, Chen Wang, Baptiste Dafflon, Lauren N. Thomas, Ian Shirley, Sarah Maebius, Colleen M. Iversen, Katrina E. Bennett

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Abstract

Temporally continuous snow depth estimates are vital for understanding changing snow patterns and impacts on permafrost in the Arctic. We trained a random forest machine learning model to predict snow depth from variability in snow–ground interface temperature. The model performed well on Alaska’s Seward Peninsula where it was trained and at Arctic evaluation sites (RMSE ≤ 0.15 m). It performed poorly at temperate sites with deeper snowpacks, partially due to training data limitations. Small temperature sensors are cheap and easy to deploy, so this technique enables spatially distributed and temporally continuous snowpack monitoring at high latitudes to an extent previously infeasible.

Original language	English
Pages (from-to)	393-400
Number of pages	8
Journal	Cryosphere
Volume	19
Issue number	1
DOIs	https://doi.org/10.5194/tc-19-393-2025
State	Published - Jan 28 2025

Funding

The Next-Generation Ecosystem Experiments in the Arctic (NGEE Arctic) project is supported by the Office of Biological and Environmental Research in the US Department of Energy's Office of Science.

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AU - Shirley, Ian

AU - Maebius, Sarah

AU - Iversen, Colleen M.

AU - Bennett, Katrina E.

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AB - Temporally continuous snow depth estimates are vital for understanding changing snow patterns and impacts on permafrost in the Arctic. We trained a random forest machine learning model to predict snow depth from variability in snow–ground interface temperature. The model performed well on Alaska’s Seward Peninsula where it was trained and at Arctic evaluation sites (RMSE ≤ 0.15 m). It performed poorly at temperate sites with deeper snowpacks, partially due to training data limitations. Small temperature sensors are cheap and easy to deploy, so this technique enables spatially distributed and temporally continuous snowpack monitoring at high latitudes to an extent previously infeasible.

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Brief communication: Monitoring snow depth using small, cheap, and easy-to-deploy snow–ground interface temperature sensors

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