Parameter Estimation in Land Surface Models: Challenges and Opportunities With Data Assimilation and Machine Learning

Nina Raoult; Natalie Douglas; Natasha MacBean; Jana Kolassa; Tristan Quaife; Andrew G. Roberts; Rosie Fisher; Istem Fer; Cédric Bacour; Katherine Dagon; Linnia Hawkins; Nuno Carvalhais; Elizabeth Cooper; Michael C. Dietze; Pierre Gentine; Thomas Kaminski; Daniel Kennedy; Hannah M. Liddy; David J.P. Moore; Philippe Peylin; Ewan Pinnington; Benjamin Sanderson; Marko Scholze; Christian Seiler; T. Luke Smallman; Noemi Vergopolan; Toni Viskari; Mathew Williams; John Zobitz

doi:10.1029/2024MS004733

Parameter Estimation in Land Surface Models: Challenges and Opportunities With Data Assimilation and Machine Learning

Nina Raoult
, Natalie Douglas
, Natasha MacBean
, Jana Kolassa
, Tristan Quaife
, Andrew G. Roberts
, Rosie Fisher
, Istem Fer
, Cédric Bacour
, Katherine Dagon
, Linnia Hawkins
, Nuno Carvalhais
, Elizabeth Cooper
, Michael C. Dietze
, Pierre Gentine
, Thomas Kaminski
, Daniel Kennedy
, Hannah M. Liddy
, David J.P. Moore
, Philippe Peylin

Ewan Pinnington, Benjamin Sanderson, Marko Scholze, Christian Seiler, T. Luke Smallman, Noemi Vergopolan, Toni Viskari, Mathew Williams, John Zobitz

Research output: Contribution to journal › Review article › peer-review

1 Scopus citations

Abstract

Accurately predicting terrestrial ecosystem responses to climate change over long-timescales is crucial for addressing global challenges. This relies on mechanistic modeling of ecosystem processes through land surface models (LSMs). Despite their importance, LSMs face significant uncertainties due to poorly constrained parameters, especially in carbon cycle predictions. This paper reviews the progress made in using data assimilation (DA) for LSM parameter optimization, focusing on carbon-water-vegetation interactions, as well as discussing the technical challenges faced by the community. These challenges include identifying sensitive model parameters and their prior distributions, characterizing errors due to observation biases and model-data inconsistencies, developing observation operators to interface between the model and the observations, tackling spatial and temporal heterogeneity as well as dealing with large and multiple data sets, and including the spin-up and historical period in the assimilation window. We outline how machine learning (ML) can help address these issues, proposing different avenues for future work that integrate ML and DA to reduce uncertainties in LSMs. We conclude by highlighting future priorities, including the need for international collaborations, to fully leverage the wealth of available Earth observation data sets, harness ML advances, and enhance the predictive capabilities of LSMs.

Original language	English (US)
Article number	e2024MS004733
Journal	Journal of Advances in Modeling Earth Systems
Volume	17
Issue number	11
DOIs	https://doi.org/10.1029/2024MS004733
State	Published - Nov 2025
Externally published	Yes

Keywords

data assimilation
land surface modeling
machine learning
model calibration
parameter estimation
uncertainty quantification

ASJC Scopus subject areas

Global and Planetary Change
Environmental Chemistry
General Earth and Planetary Sciences

Access to Document

10.1029/2024MS004733

Cite this

Raoult, N., Douglas, N., MacBean, N., Kolassa, J., Quaife, T., Roberts, A. G., Fisher, R., Fer, I., Bacour, C., Dagon, K., Hawkins, L., Carvalhais, N., Cooper, E., Dietze, M. C., Gentine, P., Kaminski, T., Kennedy, D., Liddy, H. M., Moore, D. J. P., ... Zobitz, J. (2025). Parameter Estimation in Land Surface Models: Challenges and Opportunities With Data Assimilation and Machine Learning. Journal of Advances in Modeling Earth Systems, 17(11), Article e2024MS004733. https://doi.org/10.1029/2024MS004733

Raoult, N, Douglas, N, MacBean, N, Kolassa, J, Quaife, T, Roberts, AG, Fisher, R, Fer, I, Bacour, C, Dagon, K, Hawkins, L, Carvalhais, N, Cooper, E, Dietze, MC, Gentine, P, Kaminski, T, Kennedy, D, Liddy, HM, Moore, DJP, Peylin, P, Pinnington, E, Sanderson, B, Scholze, M, Seiler, C, Smallman, TL, Vergopolan, N, Viskari, T, Williams, M & Zobitz, J 2025, 'Parameter Estimation in Land Surface Models: Challenges and Opportunities With Data Assimilation and Machine Learning', Journal of Advances in Modeling Earth Systems, vol. 17, no. 11, e2024MS004733. https://doi.org/10.1029/2024MS004733

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title = "Parameter Estimation in Land Surface Models: Challenges and Opportunities With Data Assimilation and Machine Learning",

abstract = "Accurately predicting terrestrial ecosystem responses to climate change over long-timescales is crucial for addressing global challenges. This relies on mechanistic modeling of ecosystem processes through land surface models (LSMs). Despite their importance, LSMs face significant uncertainties due to poorly constrained parameters, especially in carbon cycle predictions. This paper reviews the progress made in using data assimilation (DA) for LSM parameter optimization, focusing on carbon-water-vegetation interactions, as well as discussing the technical challenges faced by the community. These challenges include identifying sensitive model parameters and their prior distributions, characterizing errors due to observation biases and model-data inconsistencies, developing observation operators to interface between the model and the observations, tackling spatial and temporal heterogeneity as well as dealing with large and multiple data sets, and including the spin-up and historical period in the assimilation window. We outline how machine learning (ML) can help address these issues, proposing different avenues for future work that integrate ML and DA to reduce uncertainties in LSMs. We conclude by highlighting future priorities, including the need for international collaborations, to fully leverage the wealth of available Earth observation data sets, harness ML advances, and enhance the predictive capabilities of LSMs.",

keywords = "data assimilation, land surface modeling, machine learning, model calibration, parameter estimation, uncertainty quantification",

author = "Nina Raoult and Natalie Douglas and Natasha MacBean and Jana Kolassa and Tristan Quaife and Roberts, \{Andrew G.\} and Rosie Fisher and Istem Fer and C{\'e}dric Bacour and Katherine Dagon and Linnia Hawkins and Nuno Carvalhais and Elizabeth Cooper and Dietze, \{Michael C.\} and Pierre Gentine and Thomas Kaminski and Daniel Kennedy and Liddy, \{Hannah M.\} and Moore, \{David J.P.\} and Philippe Peylin and Ewan Pinnington and Benjamin Sanderson and Marko Scholze and Christian Seiler and Smallman, \{T. Luke\} and Noemi Vergopolan and Toni Viskari and Mathew Williams and John Zobitz",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Journal of Advances in Modeling Earth Systems published by Wiley Periodicals LLC on behalf of American Geophysical Union.",

year = "2025",

month = nov,

doi = "10.1029/2024MS004733",

language = "English (US)",

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T1 - Parameter Estimation in Land Surface Models

T2 - Challenges and Opportunities With Data Assimilation and Machine Learning

AU - Raoult, Nina

AU - Douglas, Natalie

AU - MacBean, Natasha

AU - Kolassa, Jana

AU - Quaife, Tristan

AU - Roberts, Andrew G.

AU - Fisher, Rosie

AU - Fer, Istem

AU - Bacour, Cédric

AU - Dagon, Katherine

AU - Hawkins, Linnia

AU - Carvalhais, Nuno

AU - Cooper, Elizabeth

AU - Dietze, Michael C.

AU - Gentine, Pierre

AU - Kaminski, Thomas

AU - Kennedy, Daniel

AU - Liddy, Hannah M.

AU - Moore, David J.P.

AU - Peylin, Philippe

AU - Pinnington, Ewan

AU - Sanderson, Benjamin

AU - Scholze, Marko

AU - Seiler, Christian

AU - Smallman, T. Luke

AU - Vergopolan, Noemi

AU - Viskari, Toni

AU - Williams, Mathew

AU - Zobitz, John

PY - 2025/11

Y1 - 2025/11

N2 - Accurately predicting terrestrial ecosystem responses to climate change over long-timescales is crucial for addressing global challenges. This relies on mechanistic modeling of ecosystem processes through land surface models (LSMs). Despite their importance, LSMs face significant uncertainties due to poorly constrained parameters, especially in carbon cycle predictions. This paper reviews the progress made in using data assimilation (DA) for LSM parameter optimization, focusing on carbon-water-vegetation interactions, as well as discussing the technical challenges faced by the community. These challenges include identifying sensitive model parameters and their prior distributions, characterizing errors due to observation biases and model-data inconsistencies, developing observation operators to interface between the model and the observations, tackling spatial and temporal heterogeneity as well as dealing with large and multiple data sets, and including the spin-up and historical period in the assimilation window. We outline how machine learning (ML) can help address these issues, proposing different avenues for future work that integrate ML and DA to reduce uncertainties in LSMs. We conclude by highlighting future priorities, including the need for international collaborations, to fully leverage the wealth of available Earth observation data sets, harness ML advances, and enhance the predictive capabilities of LSMs.

AB - Accurately predicting terrestrial ecosystem responses to climate change over long-timescales is crucial for addressing global challenges. This relies on mechanistic modeling of ecosystem processes through land surface models (LSMs). Despite their importance, LSMs face significant uncertainties due to poorly constrained parameters, especially in carbon cycle predictions. This paper reviews the progress made in using data assimilation (DA) for LSM parameter optimization, focusing on carbon-water-vegetation interactions, as well as discussing the technical challenges faced by the community. These challenges include identifying sensitive model parameters and their prior distributions, characterizing errors due to observation biases and model-data inconsistencies, developing observation operators to interface between the model and the observations, tackling spatial and temporal heterogeneity as well as dealing with large and multiple data sets, and including the spin-up and historical period in the assimilation window. We outline how machine learning (ML) can help address these issues, proposing different avenues for future work that integrate ML and DA to reduce uncertainties in LSMs. We conclude by highlighting future priorities, including the need for international collaborations, to fully leverage the wealth of available Earth observation data sets, harness ML advances, and enhance the predictive capabilities of LSMs.

KW - data assimilation

KW - land surface modeling

KW - machine learning

KW - model calibration

KW - parameter estimation

KW - uncertainty quantification

UR - https://www.scopus.com/pages/publications/105020242900

UR - https://www.scopus.com/pages/publications/105020242900#tab=citedBy

U2 - 10.1029/2024MS004733

DO - 10.1029/2024MS004733

M3 - Review article

AN - SCOPUS:105020242900

SN - 1942-2466

VL - 17

JO - Journal of Advances in Modeling Earth Systems

JF - Journal of Advances in Modeling Earth Systems

IS - 11

M1 - e2024MS004733

ER -

Parameter Estimation in Land Surface Models: Challenges and Opportunities With Data Assimilation and Machine Learning

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Keywords

ASJC Scopus subject areas

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