The Energy Exascale Earth System Model Version 3: 2. Overview of the Coupled System

Jean Christophe Golaz; Wuyin Lin; Xue Zheng; Shaocheng Xie; Andrew F. Roberts; Luke P. Van Roekel; Peter E. Thornton; Alice M. Barthel; Andrew M. Bradley; Jonathan D. Wolfe; Chengzhu Zhang; Kai Zhang; Shixuan Zhang; Xylar S. Asay-Davis; Carolyn B. Begeman; Gautam Bisht; Susannah M. Burrows; Chih Chieh Jack Chen; Yan Feng; Elizabeth C. Hunke; Robert L. Jacob; Ziming Ke; Salil Mahajan; Naser G. Mahfouz; Mathew E. Maltrud; Xiaoying Shi; Qi Tang; Christopher R. Terai; Erin E. Thomas; Hailong Wang; Jinbo Xie; Tian Zhou; Tony Bartoletti; James J. Benedict; Michael A. Brunke; Darin S. Comeau; Jiwen Fan; Ryan M. Forsyth; James G. Foucar; Oksana Guba; Walter M. Hannah; Dalei Hao; Xianglei Huang; Nicole Jeffery; Hyun Gyu Kang; Noel D. Keen; Hsiang He Lee; Jiwoo Lee; Xiaohong Liu; Azamat Mametjanov; Johannes Mülmenstädt; Mark R. Petersen; Michael J. Prather; Stephen F. Price; Yun Qian; Andrew G. Salinger; Sean P. Santos; Yunpeng Shan; Balwinder Singh; Katherine M. Smith; Xiaoliang Song; Sarat Sreepathi; Adrian K. Turner; Tom Vo; Hui Wan; Mingxuan Wu; Wandi Yu; Charles S. Zender; Xubin Zeng; Guang J. Zhang; Meng Zhang; Tao Zhang; Yuying Zhang; Renata B. McCoy; Mark A. Taylor; L. Ruby Leung; Peter M. Caldwell; David C. Bader

doi:10.1029/2025MS005302

The Energy Exascale Earth System Model Version 3: 2. Overview of the Coupled System

Jean Christophe Golaz
, Wuyin Lin
, Xue Zheng
, Shaocheng Xie
, Andrew F. Roberts
, Luke P. Van Roekel
, Peter E. Thornton
, Alice M. Barthel
, Andrew M. Bradley
, Jonathan D. Wolfe
, Chengzhu Zhang
, Kai Zhang
, Shixuan Zhang
, Xylar S. Asay-Davis
, Carolyn B. Begeman
, Gautam Bisht
, Susannah M. Burrows
, Chih Chieh Jack Chen
, Yan Feng
, Elizabeth C. Hunke

Robert L. Jacob, Ziming Ke, Salil Mahajan, Naser G. Mahfouz, Mathew E. Maltrud, Xiaoying Shi, Qi Tang, Christopher R. Terai, Erin E. Thomas, Hailong Wang, Jinbo Xie, Tian Zhou, Tony Bartoletti, James J. Benedict, Michael A. Brunke, Darin S. Comeau, Jiwen Fan, Ryan M. Forsyth, James G. Foucar, Oksana Guba, Walter M. Hannah, Dalei Hao, Xianglei Huang, Nicole Jeffery, Hyun Gyu Kang, Noel D. Keen, Hsiang He Lee, Jiwoo Lee, Xiaohong Liu, Azamat Mametjanov, Johannes Mülmenstädt, Mark R. Petersen, Michael J. Prather, Stephen F. Price, Yun Qian, Andrew G. Salinger, Sean P. Santos, Yunpeng Shan, Balwinder Singh, Katherine M. Smith, Xiaoliang Song, Sarat Sreepathi, Adrian K. Turner, Tom Vo, Hui Wan, Mingxuan Wu, Wandi Yu, Charles S. Zender, Xubin Zeng, Guang J. Zhang, Meng Zhang, Tao Zhang, Yuying Zhang, Renata B. McCoy, Mark A. Taylor, L. Ruby Leung, Peter M. Caldwell, David C. Bader

Lawrence Livermore National Laboratory
Brookhaven National Laboratory
Los Alamos National Laboratory
Oak Ridge National Laboratory
Sandia National Laboratories
Pacific Northwest National Laboratory
Argonne National Laboratory
National Center for Atmospheric Research
Desert Research Institute
Princeton University
University of Arizona
University of Michigan
Lawrence Berkeley National Laboratory
Texas A&M University
University of California at Irvine
University of California at San Diego
Department of Earth and Atmospheric Sciences, University of Houston

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

1 Scopus citations

Abstract

The Energy Exascale Earth System Model version 3 (E3SMv3) represents the latest advancement in Earth system modeling developed by the U.S. Department of Energy (DOE). Building upon previous versions, E3SMv3 introduces significant updates across its coupled components to enhance capability and improve fidelity. The atmosphere component incorporates advancements in chemistry, aerosol-cloud interactions, convection, and microphysics. The ocean features a new time-stepping scheme and a higher-resolution unstructured mesh with sub-ice-shelf cavities, while the sea ice model integrates advanced snow and ice physics for more realistic cryospheric simulations. The land model introduces prognostic vegetation dynamics and a new sub-grid topographic treatment of solar radiation. A new tri-grid configuration harmonizes the horizontal grids of the land and river components for improved process coupling. It is enabled by a new non-linear remapping between the atmosphere and land. E3SMv3 underwent extensive testing through a comprehensive simulation campaign, including pre-industrial control, idealized (Formula presented.) experiments, and historical simulations spanning 1850–2024. The model demonstrates significant improvements in simulating the evolution of the historical surface temperature, particularly addressing the “pothole cooling” bias in earlier versions. Reduced aerosol-related forcing contributes to more realistic radiative forcing and better alignment with the observational record. Ocean heat content (OHC) and sea ice trends are also improved as a result.

Original language	English
Article number	e2025MS005302
Journal	Journal of Advances in Modeling Earth Systems
Volume	18
Issue number	4
DOIs	https://doi.org/10.1029/2025MS005302
State	Published - Apr 2026
Externally published	Yes

Keywords

E3SM
Earth system modeling

Access to Document

10.1029/2025MS005302

Cite this

Golaz, J. C., Lin, W., Zheng, X., Xie, S., Roberts, A. F., Van Roekel, L. P., Thornton, P. E., Barthel, A. M., Bradley, A. M., Wolfe, J. D., Zhang, C., Zhang, K., Zhang, S., Asay-Davis, X. S., Begeman, C. B., Bisht, G., Burrows, S. M., Chen, C. C. J., Feng, Y., ... Bader, D. C. (2026). The Energy Exascale Earth System Model Version 3: 2. Overview of the Coupled System. Journal of Advances in Modeling Earth Systems, 18(4), Article e2025MS005302. https://doi.org/10.1029/2025MS005302

@article{a4e95ba22c2446b88d40deb0e8a9cc77,

title = "The Energy Exascale Earth System Model Version 3: 2. Overview of the Coupled System",

abstract = "The Energy Exascale Earth System Model version 3 (E3SMv3) represents the latest advancement in Earth system modeling developed by the U.S. Department of Energy (DOE). Building upon previous versions, E3SMv3 introduces significant updates across its coupled components to enhance capability and improve fidelity. The atmosphere component incorporates advancements in chemistry, aerosol-cloud interactions, convection, and microphysics. The ocean features a new time-stepping scheme and a higher-resolution unstructured mesh with sub-ice-shelf cavities, while the sea ice model integrates advanced snow and ice physics for more realistic cryospheric simulations. The land model introduces prognostic vegetation dynamics and a new sub-grid topographic treatment of solar radiation. A new tri-grid configuration harmonizes the horizontal grids of the land and river components for improved process coupling. It is enabled by a new non-linear remapping between the atmosphere and land. E3SMv3 underwent extensive testing through a comprehensive simulation campaign, including pre-industrial control, idealized (Formula presented.) experiments, and historical simulations spanning 1850–2024. The model demonstrates significant improvements in simulating the evolution of the historical surface temperature, particularly addressing the “pothole cooling” bias in earlier versions. Reduced aerosol-related forcing contributes to more realistic radiative forcing and better alignment with the observational record. Ocean heat content (OHC) and sea ice trends are also improved as a result.",

keywords = "E3SM, Earth system modeling",

author = "Golaz, \{Jean Christophe\} and Wuyin Lin and Xue Zheng and Shaocheng Xie and Roberts, \{Andrew F.\} and \{Van Roekel\}, \{Luke P.\} and Thornton, \{Peter E.\} and Barthel, \{Alice M.\} and Bradley, \{Andrew M.\} and Wolfe, \{Jonathan D.\} and Chengzhu Zhang and Kai Zhang and Shixuan Zhang and Asay-Davis, \{Xylar S.\} and Begeman, \{Carolyn B.\} and Gautam Bisht and Burrows, \{Susannah M.\} and Chen, \{Chih Chieh Jack\} and Yan Feng and Hunke, \{Elizabeth C.\} and Jacob, \{Robert L.\} and Ziming Ke and Salil Mahajan and Mahfouz, \{Naser G.\} and Maltrud, \{Mathew E.\} and Xiaoying Shi and Qi Tang and Terai, \{Christopher R.\} and Thomas, \{Erin E.\} and Hailong Wang and Jinbo Xie and Tian Zhou and Tony Bartoletti and Benedict, \{James J.\} and Brunke, \{Michael A.\} and Comeau, \{Darin S.\} and Jiwen Fan and Forsyth, \{Ryan M.\} and Foucar, \{James G.\} and Oksana Guba and Hannah, \{Walter M.\} and Dalei Hao and Xianglei Huang and Nicole Jeffery and Kang, \{Hyun Gyu\} and Keen, \{Noel D.\} and Lee, \{Hsiang He\} and Jiwoo Lee and Xiaohong Liu and Azamat Mametjanov and Johannes M{\"u}lmenst{\"a}dt and Petersen, \{Mark R.\} and Prather, \{Michael J.\} and Price, \{Stephen F.\} and Yun Qian and Salinger, \{Andrew G.\} and Santos, \{Sean P.\} and Yunpeng Shan and Balwinder Singh and Smith, \{Katherine M.\} and Xiaoliang Song and Sarat Sreepathi and Turner, \{Adrian K.\} and Tom Vo and Hui Wan and Mingxuan Wu and Wandi Yu and Zender, \{Charles S.\} and Xubin Zeng and Zhang, \{Guang J.\} and Meng Zhang and Tao Zhang and Yuying Zhang and McCoy, \{Renata B.\} and Taylor, \{Mark A.\} and Leung, \{L. Ruby\} and Caldwell, \{Peter M.\} and Bader, \{David C.\}",

note = "Publisher Copyright: {\textcopyright} 2026 The Author(s). Journal of Advances in Modeling Earth Systems published by Wiley Periodicals LLC on behalf of American Geophysical Union.",

year = "2026",

month = apr,

doi = "10.1029/2025MS005302",

language = "English",

volume = "18",

journal = "Journal of Advances in Modeling Earth Systems",

issn = "1942-2466",

publisher = "John Wiley and Sons Inc.",

number = "4",

}

Golaz, JC, Lin, W, Zheng, X, Xie, S, Roberts, AF, Van Roekel, LP, Thornton, PE, Barthel, AM, Bradley, AM, Wolfe, JD, Zhang, C, Zhang, K, Zhang, S, Asay-Davis, XS, Begeman, CB, Bisht, G, Burrows, SM, Chen, CCJ, Feng, Y, Hunke, EC, Jacob, RL, Ke, Z, Mahajan, S, Mahfouz, NG, Maltrud, ME, Shi, X, Tang, Q, Terai, CR, Thomas, EE, Wang, H, Xie, J, Zhou, T, Bartoletti, T, Benedict, JJ, Brunke, MA, Comeau, DS, Fan, J, Forsyth, RM, Foucar, JG, Guba, O, Hannah, WM, Hao, D, Huang, X, Jeffery, N, Kang, HG, Keen, ND, Lee, HH, Lee, J, Liu, X, Mametjanov, A, Mülmenstädt, J, Petersen, MR, Prather, MJ, Price, SF, Qian, Y, Salinger, AG, Santos, SP, Shan, Y, Singh, B, Smith, KM, Song, X, Sreepathi, S, Turner, AK, Vo, T, Wan, H, Wu, M, Yu, W, Zender, CS, Zeng, X, Zhang, GJ, Zhang, M, Zhang, T, Zhang, Y, McCoy, RB, Taylor, MA, Leung, LR, Caldwell, PM & Bader, DC 2026, 'The Energy Exascale Earth System Model Version 3: 2. Overview of the Coupled System', Journal of Advances in Modeling Earth Systems, vol. 18, no. 4, e2025MS005302. https://doi.org/10.1029/2025MS005302

TY - JOUR

T1 - The Energy Exascale Earth System Model Version 3

T2 - 2. Overview of the Coupled System

AU - Golaz, Jean Christophe

AU - Lin, Wuyin

AU - Zheng, Xue

AU - Xie, Shaocheng

AU - Roberts, Andrew F.

AU - Van Roekel, Luke P.

AU - Thornton, Peter E.

AU - Barthel, Alice M.

AU - Bradley, Andrew M.

AU - Wolfe, Jonathan D.

AU - Zhang, Chengzhu

AU - Zhang, Kai

AU - Zhang, Shixuan

AU - Asay-Davis, Xylar S.

AU - Begeman, Carolyn B.

AU - Bisht, Gautam

AU - Burrows, Susannah M.

AU - Chen, Chih Chieh Jack

AU - Feng, Yan

AU - Hunke, Elizabeth C.

AU - Jacob, Robert L.

AU - Ke, Ziming

AU - Mahajan, Salil

AU - Mahfouz, Naser G.

AU - Maltrud, Mathew E.

AU - Shi, Xiaoying

AU - Tang, Qi

AU - Terai, Christopher R.

AU - Thomas, Erin E.

AU - Wang, Hailong

AU - Xie, Jinbo

AU - Zhou, Tian

AU - Bartoletti, Tony

AU - Benedict, James J.

AU - Brunke, Michael A.

AU - Comeau, Darin S.

AU - Fan, Jiwen

AU - Forsyth, Ryan M.

AU - Foucar, James G.

AU - Guba, Oksana

AU - Hannah, Walter M.

AU - Hao, Dalei

AU - Huang, Xianglei

AU - Jeffery, Nicole

AU - Kang, Hyun Gyu

AU - Keen, Noel D.

AU - Lee, Hsiang He

AU - Lee, Jiwoo

AU - Liu, Xiaohong

AU - Mametjanov, Azamat

AU - Mülmenstädt, Johannes

AU - Petersen, Mark R.

AU - Prather, Michael J.

AU - Price, Stephen F.

AU - Qian, Yun

AU - Salinger, Andrew G.

AU - Santos, Sean P.

AU - Shan, Yunpeng

AU - Singh, Balwinder

AU - Smith, Katherine M.

AU - Song, Xiaoliang

AU - Sreepathi, Sarat

AU - Turner, Adrian K.

AU - Vo, Tom

AU - Wan, Hui

AU - Wu, Mingxuan

AU - Yu, Wandi

AU - Zender, Charles S.

AU - Zeng, Xubin

AU - Zhang, Guang J.

AU - Zhang, Meng

AU - Zhang, Tao

AU - Zhang, Yuying

AU - McCoy, Renata B.

AU - Taylor, Mark A.

AU - Leung, L. Ruby

AU - Caldwell, Peter M.

AU - Bader, David C.

PY - 2026/4

Y1 - 2026/4

N2 - The Energy Exascale Earth System Model version 3 (E3SMv3) represents the latest advancement in Earth system modeling developed by the U.S. Department of Energy (DOE). Building upon previous versions, E3SMv3 introduces significant updates across its coupled components to enhance capability and improve fidelity. The atmosphere component incorporates advancements in chemistry, aerosol-cloud interactions, convection, and microphysics. The ocean features a new time-stepping scheme and a higher-resolution unstructured mesh with sub-ice-shelf cavities, while the sea ice model integrates advanced snow and ice physics for more realistic cryospheric simulations. The land model introduces prognostic vegetation dynamics and a new sub-grid topographic treatment of solar radiation. A new tri-grid configuration harmonizes the horizontal grids of the land and river components for improved process coupling. It is enabled by a new non-linear remapping between the atmosphere and land. E3SMv3 underwent extensive testing through a comprehensive simulation campaign, including pre-industrial control, idealized (Formula presented.) experiments, and historical simulations spanning 1850–2024. The model demonstrates significant improvements in simulating the evolution of the historical surface temperature, particularly addressing the “pothole cooling” bias in earlier versions. Reduced aerosol-related forcing contributes to more realistic radiative forcing and better alignment with the observational record. Ocean heat content (OHC) and sea ice trends are also improved as a result.

AB - The Energy Exascale Earth System Model version 3 (E3SMv3) represents the latest advancement in Earth system modeling developed by the U.S. Department of Energy (DOE). Building upon previous versions, E3SMv3 introduces significant updates across its coupled components to enhance capability and improve fidelity. The atmosphere component incorporates advancements in chemistry, aerosol-cloud interactions, convection, and microphysics. The ocean features a new time-stepping scheme and a higher-resolution unstructured mesh with sub-ice-shelf cavities, while the sea ice model integrates advanced snow and ice physics for more realistic cryospheric simulations. The land model introduces prognostic vegetation dynamics and a new sub-grid topographic treatment of solar radiation. A new tri-grid configuration harmonizes the horizontal grids of the land and river components for improved process coupling. It is enabled by a new non-linear remapping between the atmosphere and land. E3SMv3 underwent extensive testing through a comprehensive simulation campaign, including pre-industrial control, idealized (Formula presented.) experiments, and historical simulations spanning 1850–2024. The model demonstrates significant improvements in simulating the evolution of the historical surface temperature, particularly addressing the “pothole cooling” bias in earlier versions. Reduced aerosol-related forcing contributes to more realistic radiative forcing and better alignment with the observational record. Ocean heat content (OHC) and sea ice trends are also improved as a result.

KW - E3SM

KW - Earth system modeling

UR - https://www.scopus.com/pages/publications/105035656329

U2 - 10.1029/2025MS005302

DO - 10.1029/2025MS005302

M3 - Article

AN - SCOPUS:105035656329

SN - 1942-2466

VL - 18

JO - Journal of Advances in Modeling Earth Systems

JF - Journal of Advances in Modeling Earth Systems

IS - 4

M1 - e2025MS005302

ER -

The Energy Exascale Earth System Model Version 3: 2. Overview of the Coupled System

Abstract

Keywords

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