The Earth system model CLIMBER-X v1.0 – Part 1: Climate model description and validation
The newly developed fast Earth system model CLIMBER-X is presented. The climate component of CLIMBER-X consists of a 2.5-D semi-empirical statistical-dynamical atmosphere model, a 3-D frictional-geostrophic ocean model, a dynamic-thermodynamic sea ice model and a land surface model. All the model co...
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ftleibnizopen:oai:oai.leibnizopen.de:rkGVhIgBdbrxVwz6-CQn 2023-06-18T03:41:15+02:00 The Earth system model CLIMBER-X v1.0 – Part 1: Climate model description and validation Willeit, Matteo Ganopolski, Andrey Robinson, Alexander Edwards, Neil R. 2022 application/pdf https://oa.tib.eu/renate/handle/123456789/11864 https://doi.org/10.34657/10897 eng eng Katlenburg-Lindau : Copernicus CC BY 4.0 Unported https://creativecommons.org/licenses/by/4.0 Geoscientific model development : GMD 15 (2022), Nr. 14 boundary condition carbon cycle climate change land surface thermodynamic property 910 article Text 2022 ftleibnizopen https://doi.org/10.34657/10897 2023-06-04T23:15:07Z The newly developed fast Earth system model CLIMBER-X is presented. The climate component of CLIMBER-X consists of a 2.5-D semi-empirical statistical-dynamical atmosphere model, a 3-D frictional-geostrophic ocean model, a dynamic-thermodynamic sea ice model and a land surface model. All the model components are discretized on a regular lat-long grid with a horizontal resolution of 5 ° ×5 °. The model has a throughput of ° ∼ 10 000 simulation years per day on a single node with 16 CPUs on a high-performance computer and is designed to simulate the evolution of the Earth system on temporal scales ranging from decades to >100000 years. A comprehensive evaluation of the model performance for the present day and the historical period shows that CLIMBER-X is capable of realistically reproducing many observed climate characteristics, with results that generally lie within the range of state-of-the-art general circulation models. The analysis of model performance is complemented by a thorough assessment of climate feedbacks and model sensitivities to changes in external forcings and boundary conditions. Limitations and applicability of the model are critically discussed. CLIMBER-X also includes a detailed representation of the global carbon cycle and is coupled to an ice sheet model, which will be described in separate papers. CLIMBER-X is available as open-source code and is expected to be a useful tool for studying past climate changes and for the investigation of the long-term future evolution of the climate. Leibniz_Fonds publishedVersion Article in Journal/Newspaper Ice Sheet Sea ice LeibnizOpen (The Leibniz Association) |
institution |
Open Polar |
collection |
LeibnizOpen (The Leibniz Association) |
op_collection_id |
ftleibnizopen |
language |
English |
topic |
boundary condition carbon cycle climate change land surface thermodynamic property 910 |
spellingShingle |
boundary condition carbon cycle climate change land surface thermodynamic property 910 Willeit, Matteo Ganopolski, Andrey Robinson, Alexander Edwards, Neil R. The Earth system model CLIMBER-X v1.0 – Part 1: Climate model description and validation |
topic_facet |
boundary condition carbon cycle climate change land surface thermodynamic property 910 |
description |
The newly developed fast Earth system model CLIMBER-X is presented. The climate component of CLIMBER-X consists of a 2.5-D semi-empirical statistical-dynamical atmosphere model, a 3-D frictional-geostrophic ocean model, a dynamic-thermodynamic sea ice model and a land surface model. All the model components are discretized on a regular lat-long grid with a horizontal resolution of 5 ° ×5 °. The model has a throughput of ° ∼ 10 000 simulation years per day on a single node with 16 CPUs on a high-performance computer and is designed to simulate the evolution of the Earth system on temporal scales ranging from decades to >100000 years. A comprehensive evaluation of the model performance for the present day and the historical period shows that CLIMBER-X is capable of realistically reproducing many observed climate characteristics, with results that generally lie within the range of state-of-the-art general circulation models. The analysis of model performance is complemented by a thorough assessment of climate feedbacks and model sensitivities to changes in external forcings and boundary conditions. Limitations and applicability of the model are critically discussed. CLIMBER-X also includes a detailed representation of the global carbon cycle and is coupled to an ice sheet model, which will be described in separate papers. CLIMBER-X is available as open-source code and is expected to be a useful tool for studying past climate changes and for the investigation of the long-term future evolution of the climate. Leibniz_Fonds publishedVersion |
format |
Article in Journal/Newspaper |
author |
Willeit, Matteo Ganopolski, Andrey Robinson, Alexander Edwards, Neil R. |
author_facet |
Willeit, Matteo Ganopolski, Andrey Robinson, Alexander Edwards, Neil R. |
author_sort |
Willeit, Matteo |
title |
The Earth system model CLIMBER-X v1.0 – Part 1: Climate model description and validation |
title_short |
The Earth system model CLIMBER-X v1.0 – Part 1: Climate model description and validation |
title_full |
The Earth system model CLIMBER-X v1.0 – Part 1: Climate model description and validation |
title_fullStr |
The Earth system model CLIMBER-X v1.0 – Part 1: Climate model description and validation |
title_full_unstemmed |
The Earth system model CLIMBER-X v1.0 – Part 1: Climate model description and validation |
title_sort |
earth system model climber-x v1.0 – part 1: climate model description and validation |
publisher |
Katlenburg-Lindau : Copernicus |
publishDate |
2022 |
url |
https://oa.tib.eu/renate/handle/123456789/11864 https://doi.org/10.34657/10897 |
genre |
Ice Sheet Sea ice |
genre_facet |
Ice Sheet Sea ice |
op_source |
Geoscientific model development : GMD 15 (2022), Nr. 14 |
op_rights |
CC BY 4.0 Unported https://creativecommons.org/licenses/by/4.0 |
op_doi |
https://doi.org/10.34657/10897 |
_version_ |
1769006739376570368 |