Physics-aware machine learning for glacier ice thickness estimation: a case study for Svalbard

Viola Steidl; Jonathan Louis Bamber; Xiao Xiang Zhu

doi:10.5194/tc-19-645-2025

Physics-aware machine learning for glacier ice thickness estimation: a case study for Svalbard

Viola Steidl^*, Jonathan Louis Bamber, Xiao Xiang Zhu

^*Corresponding author for this work

Research output: Contribution to journal › Article (Academic Journal) › peer-review

5 Citations (Scopus)

Abstract

The ice thickness of the world's glaciers is mostly unmeasured, and physics-based models to reconstruct ice thickness cannot always deliver accurate estimates. In this study, we use deep learning paired with physical knowledge to generate ice thickness estimates for all glaciers of Spitsbergen, Barentsøya, and Edgeøya in Svalbard. We incorporate mass conservation and other physically derived conditions into a neural network to predict plausible ice thicknesses even for glaciers without any in situ ice thickness measurements. With a glacier-wise cross-validation scheme, we evaluate the performance of the physics-informed neural network. The results of these proof-of-concept experiments let us identify several challenges and opportunities that affect the model's performance in a real-world setting.

Original language	English
Pages (from-to)	645-661
Number of pages	17
Journal	Cryosphere
Volume	19
Issue number	2
DOIs	https://doi.org/10.5194/tc-19-645-2025
Publication status	Published - 7 Feb 2025

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© 2025 Viola Steidl et al.

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Bristol Glaciology Centre

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title = "Physics-aware machine learning for glacier ice thickness estimation: a case study for Svalbard",

abstract = "The ice thickness of the world's glaciers is mostly unmeasured, and physics-based models to reconstruct ice thickness cannot always deliver accurate estimates. In this study, we use deep learning paired with physical knowledge to generate ice thickness estimates for all glaciers of Spitsbergen, Barents{\o}ya, and Edge{\o}ya in Svalbard. We incorporate mass conservation and other physically derived conditions into a neural network to predict plausible ice thicknesses even for glaciers without any in situ ice thickness measurements. With a glacier-wise cross-validation scheme, we evaluate the performance of the physics-informed neural network. The results of these proof-of-concept experiments let us identify several challenges and opportunities that affect the model's performance in a real-world setting.",

author = "Viola Steidl and Bamber, \{Jonathan Louis\} and Zhu, \{Xiao Xiang\}",

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T1 - Physics-aware machine learning for glacier ice thickness estimation

T2 - a case study for Svalbard

AU - Steidl, Viola

AU - Bamber, Jonathan Louis

AU - Zhu, Xiao Xiang

PY - 2025/2/7

Y1 - 2025/2/7

N2 - The ice thickness of the world's glaciers is mostly unmeasured, and physics-based models to reconstruct ice thickness cannot always deliver accurate estimates. In this study, we use deep learning paired with physical knowledge to generate ice thickness estimates for all glaciers of Spitsbergen, Barentsøya, and Edgeøya in Svalbard. We incorporate mass conservation and other physically derived conditions into a neural network to predict plausible ice thicknesses even for glaciers without any in situ ice thickness measurements. With a glacier-wise cross-validation scheme, we evaluate the performance of the physics-informed neural network. The results of these proof-of-concept experiments let us identify several challenges and opportunities that affect the model's performance in a real-world setting.

AB - The ice thickness of the world's glaciers is mostly unmeasured, and physics-based models to reconstruct ice thickness cannot always deliver accurate estimates. In this study, we use deep learning paired with physical knowledge to generate ice thickness estimates for all glaciers of Spitsbergen, Barentsøya, and Edgeøya in Svalbard. We incorporate mass conservation and other physically derived conditions into a neural network to predict plausible ice thicknesses even for glaciers without any in situ ice thickness measurements. With a glacier-wise cross-validation scheme, we evaluate the performance of the physics-informed neural network. The results of these proof-of-concept experiments let us identify several challenges and opportunities that affect the model's performance in a real-world setting.

UR - https://www.scopus.com/pages/publications/85218149122

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DO - 10.5194/tc-19-645-2025

M3 - Article (Academic Journal)

AN - SCOPUS:85218149122

SN - 1994-0416

VL - 19

SP - 645

EP - 661

JO - Cryosphere

JF - Cryosphere

IS - 2

ER -

Physics-aware machine learning for glacier ice thickness estimation: a case study for Svalbard

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