The PolarRES dataset: a state-of-the-art regional climate model ensemble for understanding Antarctic climate

Ella Gilbert; José Abraham Torres-Alavez; Marte G. Hofsteenge; Willem Jan van de Berg; Fredrik Boberg; Ole Bøssing Christensen; Christiaan Timo van Dalum; Xavier Fettweis; Siddharth Gumber; Nicolaj Hansen; Christoph Kittel; Clara Lambin; Damien Maure; Ruth Mottram; Martin Olesen; Andrew Orr; Tony Phillips; Maurice van Tiggelen; Kristiina Verro; Priscilla A. Mooney

doi:10.5194/tc-20-2629-2026

The PolarRES dataset: a state-of-the-art regional climate model ensemble for understanding Antarctic climate

Ella Gilbert^*
, José Abraham Torres-Alavez
, Marte G. Hofsteenge^*
, Willem Jan van de Berg
, Fredrik Boberg
, Ole Bøssing Christensen
, Christiaan Timo van Dalum
, Xavier Fettweis
, Siddharth Gumber
, Nicolaj Hansen
, Christoph Kittel
, Clara Lambin
, Damien Maure
, Ruth Mottram
, Martin Olesen
, Andrew Orr
, Tony Phillips
, Maurice van Tiggelen
, Kristiina Verro
, Priscilla A. Mooney

^*Corresponding author for this work

British Antarctic Survey
Danish Meteorological Institute
Utrecht University
Royal Netherlands Meteorological Institute
Université Grenoble Alpes
Vrije Universiteit Brussel
University of Liege
Bjerknes Centre for Climate Research

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

Abstract

Antarctica's weather and climate have global impacts, influencing weather patterns, ocean currents and sea levels worldwide. However, Antarctica is vast and complex, and the atmospheric processes that govern its climate are strongly influenced by its steep terrain, particularly around the coastal periphery. Our scientific understanding of this complex environment is hampered by the lack of reliable observations and gridded datasets at sufficiently high spatial and temporal resolution. High-resolution regional climate models, RCMs, can provide a solution to the sparsity of observational data and low resolution of reanalyses, facilitating more in-depth assessments of crucial climate variables like precipitation, wind and temperature that are strongly influenced by topography. Here we present and evaluate a comprehensive, high-quality, ∼ 11 km resolution RCM dataset, the PolarRES ensemble, for the period 2000–2019. We show that the ensemble largely out-performs ERA5, especially with regard to variables like coastal winds and precipitation. There are no consistent seasonal differences in biases, but there are persistent regional biases. Victoria Land and the Trans-Antarctic Mountains are the regions the RCMs and ERA5 struggle the most with, which suggests that further investigation and model development is needed in this area. Each RCM has strengths and limitations, but overall the ensemble captures the observed weather and climate of Antarctica well. The PolarRES ensemble offers a novel and exciting way of evaluating climate processes and features, and we encourage researchers to use the data, which are freely available, to explore pertinent climate questions of local, regional and global significance.

Original language	English
Pages (from-to)	2629-2658
Number of pages	30
Journal	Cryosphere
Volume	20
Issue number	5
DOIs	https://doi.org/10.5194/tc-20-2629-2026
Publication status	Published - 6 May 2026

Bibliographical note

Publisher Copyright:
© 2026 Ella Gilbert et al.

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 13 Climate Action
SDG 15 Life on Land

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tc-20-2629-2026Final published version, 23.9 MBLicence: CC BY

Cite this

Gilbert, E., Torres-Alavez, J. A., Hofsteenge, M. G., van de Berg, W. J., Boberg, F., Christensen, O. B., van Dalum, C. T., Fettweis, X., Gumber, S., Hansen, N., Kittel, C., Lambin, C., Maure, D., Mottram, R., Olesen, M., Orr, A., Phillips, T., van Tiggelen, M., Verro, K., & Mooney, P. A. (2026). The PolarRES dataset: a state-of-the-art regional climate model ensemble for understanding Antarctic climate. Cryosphere, 20(5), 2629-2658. https://doi.org/10.5194/tc-20-2629-2026

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title = "The PolarRES dataset: a state-of-the-art regional climate model ensemble for understanding Antarctic climate",

abstract = "Antarctica's weather and climate have global impacts, influencing weather patterns, ocean currents and sea levels worldwide. However, Antarctica is vast and complex, and the atmospheric processes that govern its climate are strongly influenced by its steep terrain, particularly around the coastal periphery. Our scientific understanding of this complex environment is hampered by the lack of reliable observations and gridded datasets at sufficiently high spatial and temporal resolution. High-resolution regional climate models, RCMs, can provide a solution to the sparsity of observational data and low resolution of reanalyses, facilitating more in-depth assessments of crucial climate variables like precipitation, wind and temperature that are strongly influenced by topography. Here we present and evaluate a comprehensive, high-quality, ∼ 11 km resolution RCM dataset, the PolarRES ensemble, for the period 2000–2019. We show that the ensemble largely out-performs ERA5, especially with regard to variables like coastal winds and precipitation. There are no consistent seasonal differences in biases, but there are persistent regional biases. Victoria Land and the Trans-Antarctic Mountains are the regions the RCMs and ERA5 struggle the most with, which suggests that further investigation and model development is needed in this area. Each RCM has strengths and limitations, but overall the ensemble captures the observed weather and climate of Antarctica well. The PolarRES ensemble offers a novel and exciting way of evaluating climate processes and features, and we encourage researchers to use the data, which are freely available, to explore pertinent climate questions of local, regional and global significance.",

author = "Ella Gilbert and Torres-Alavez, \{Jos{\'e} Abraham\} and Hofsteenge, \{Marte G.\} and \{van de Berg\}, \{Willem Jan\} and Fredrik Boberg and Christensen, \{Ole B{\o}ssing\} and \{van Dalum\}, \{Christiaan Timo\} and Xavier Fettweis and Siddharth Gumber and Nicolaj Hansen and Christoph Kittel and Clara Lambin and Damien Maure and Ruth Mottram and Martin Olesen and Andrew Orr and Tony Phillips and \{van Tiggelen\}, Maurice and Kristiina Verro and Mooney, \{Priscilla A.\}",

note = "Publisher Copyright: {\textcopyright} 2026 Ella Gilbert et al.",

year = "2026",

month = may,

day = "6",

doi = "10.5194/tc-20-2629-2026",

language = "English",

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Gilbert, E, Torres-Alavez, JA, Hofsteenge, MG , van de Berg, WJ, Boberg, F, Christensen, OB, van Dalum, CT, Fettweis, X, Gumber, S, Hansen, N, Kittel, C, Lambin, C, Maure, D, Mottram, R, Olesen, M, Orr, A, Phillips, T, van Tiggelen, M, Verro, K & Mooney, PA 2026, 'The PolarRES dataset: a state-of-the-art regional climate model ensemble for understanding Antarctic climate', Cryosphere, vol. 20, no. 5, pp. 2629-2658. https://doi.org/10.5194/tc-20-2629-2026

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T2 - a state-of-the-art regional climate model ensemble for understanding Antarctic climate

AU - Gilbert, Ella

AU - Torres-Alavez, José Abraham

AU - Hofsteenge, Marte G.

AU - van de Berg, Willem Jan

AU - Boberg, Fredrik

AU - Christensen, Ole Bøssing

AU - van Dalum, Christiaan Timo

AU - Fettweis, Xavier

AU - Gumber, Siddharth

AU - Hansen, Nicolaj

AU - Kittel, Christoph

AU - Lambin, Clara

AU - Maure, Damien

AU - Mottram, Ruth

AU - Olesen, Martin

AU - Orr, Andrew

AU - Phillips, Tony

AU - van Tiggelen, Maurice

AU - Verro, Kristiina

AU - Mooney, Priscilla A.

PY - 2026/5/6

Y1 - 2026/5/6

N2 - Antarctica's weather and climate have global impacts, influencing weather patterns, ocean currents and sea levels worldwide. However, Antarctica is vast and complex, and the atmospheric processes that govern its climate are strongly influenced by its steep terrain, particularly around the coastal periphery. Our scientific understanding of this complex environment is hampered by the lack of reliable observations and gridded datasets at sufficiently high spatial and temporal resolution. High-resolution regional climate models, RCMs, can provide a solution to the sparsity of observational data and low resolution of reanalyses, facilitating more in-depth assessments of crucial climate variables like precipitation, wind and temperature that are strongly influenced by topography. Here we present and evaluate a comprehensive, high-quality, ∼ 11 km resolution RCM dataset, the PolarRES ensemble, for the period 2000–2019. We show that the ensemble largely out-performs ERA5, especially with regard to variables like coastal winds and precipitation. There are no consistent seasonal differences in biases, but there are persistent regional biases. Victoria Land and the Trans-Antarctic Mountains are the regions the RCMs and ERA5 struggle the most with, which suggests that further investigation and model development is needed in this area. Each RCM has strengths and limitations, but overall the ensemble captures the observed weather and climate of Antarctica well. The PolarRES ensemble offers a novel and exciting way of evaluating climate processes and features, and we encourage researchers to use the data, which are freely available, to explore pertinent climate questions of local, regional and global significance.

AB - Antarctica's weather and climate have global impacts, influencing weather patterns, ocean currents and sea levels worldwide. However, Antarctica is vast and complex, and the atmospheric processes that govern its climate are strongly influenced by its steep terrain, particularly around the coastal periphery. Our scientific understanding of this complex environment is hampered by the lack of reliable observations and gridded datasets at sufficiently high spatial and temporal resolution. High-resolution regional climate models, RCMs, can provide a solution to the sparsity of observational data and low resolution of reanalyses, facilitating more in-depth assessments of crucial climate variables like precipitation, wind and temperature that are strongly influenced by topography. Here we present and evaluate a comprehensive, high-quality, ∼ 11 km resolution RCM dataset, the PolarRES ensemble, for the period 2000–2019. We show that the ensemble largely out-performs ERA5, especially with regard to variables like coastal winds and precipitation. There are no consistent seasonal differences in biases, but there are persistent regional biases. Victoria Land and the Trans-Antarctic Mountains are the regions the RCMs and ERA5 struggle the most with, which suggests that further investigation and model development is needed in this area. Each RCM has strengths and limitations, but overall the ensemble captures the observed weather and climate of Antarctica well. The PolarRES ensemble offers a novel and exciting way of evaluating climate processes and features, and we encourage researchers to use the data, which are freely available, to explore pertinent climate questions of local, regional and global significance.

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DO - 10.5194/tc-20-2629-2026

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AN - SCOPUS:105039048425

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JO - Cryosphere

JF - Cryosphere

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ER -

The PolarRES dataset: a state-of-the-art regional climate model ensemble for understanding Antarctic climate

Abstract

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