Ice bottom evolution derived from thermistor string-based ice mass balance buoy observations

Digital information on sea ice extent, thickness, volume, and distribution is crucial for understanding Earth's climate system. The Snow and Ice Mass Balance Apparatus (SIMBA) is used to determine snow and ice temperatures in Arctic, Antarctic, ice-covered seas, and boreal lakes. Snow depth and...

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Bibliographic Details
Published inInternational journal of digital earth Vol. 16; no. 1; pp. 3085 - 3104
Main Authors Liao, Zeliang, Cheng, Yubing, Jiang, Ying, Li, Mengmeng, Cheng, Bin, Sandven, Stein
Format Journal Article
LanguageEnglish
Published Abingdon Taylor & Francis Ltd 2023
Taylor & Francis Group
Subjects
Bias
Climate system
Coefficients
Correlation coefficient
Correlation coefficients
Evolution
Ice cover
Ice thickness
ice-bottom evolution
Kalman filters
Lake ice
lake ice thickness
Lakes
Mass balance
Neural networks
nonlinear filtering
Robustness (mathematics)
Sea ice
sea ice thickness
Snow depth
Thermistors
Thermodynamic equilibrium
Thickness
Vertical profiles
Wavelet analysis
Arctic region
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Summary:Digital information on sea ice extent, thickness, volume, and distribution is crucial for understanding Earth's climate system. The Snow and Ice Mass Balance Apparatus (SIMBA) is used to determine snow and ice temperatures in Arctic, Antarctic, ice-covered seas, and boreal lakes. Snow depth and ice thickness are derived from SIMBA temperature regimes (SIMBA_ET and SIMBA_HT). In warm conditions, SIMBA_ET temperature-based ice thickness may have errors due to the isothermal vertical profile. SIMBA_HT provides a visible ice-bottom interface for manual quantification. We propose an unmanned approach, combining neural networks, wavelet analysis, and Kalman filtering (NWK), to mathematically establish NWK and retrieve ice bottoms from various SIMBA_HT datasets. In the Arctic, NWK-derived total thickness showed a bias range of −5.64 cm to 4.01 cm and a correlation coefficient of 95%−99%. For Baltic Sea ice, values ranged from 1.31 cm to 2.41 cm (88%−98% correlation), and for boreal lake ice, −0.7 cm to 2.6 cm (75%−83% correlation). During ice growth, thermal equilibrium, and melting, the bias varied from −3.93 cm to 2.37 cm, −1.92 cm to 0.04 cm, and −4.90 cm to 3.96 cm, with correlation coefficients of 76%−99%. These results demonstrate NWK's robustness in retrieving ice bottom evolution in different water environments.
ISSN:1753-8947
1753-8955
DOI:10.1080/17538947.2023.2242326