Wheat crop models underestimate drought stress in semi-arid and Mediterranean environments

H. Webber; D. Cooke; C. Wang; S. Asseng; P. Martre; F. Ewert; B. Kimball; G. Hoogenboom; S. Evett; A. Chanzy; S. Garrigues; A. Olioso; K.S. Copeland; J.L. Steiner; D. Cammarano; Y. Chen; M. Crépeau; E. Diamantopoulos; R. Ferrise; L. Manceau; T. Gaiser; Y. Gao; S. Gayler; J.R. Guarin; T. Hunt; G. Jégo; G. Padovan; E. Pattey; D. Ripoche; A. Rodríguez; M. Ruiz-Ramos; V. Shelia; A.K. Srivastava; I. Supit; F. Tao; K. Thorp; M. Viswanathan; T. Weber; J. White

doi:10.1016/j.fcr.2025.110032

Wheat crop models underestimate drought stress in semi-arid and Mediterranean environments

H. Webber^*, D. Cooke, C. Wang, S. Asseng, P. Martre, F. Ewert, B. Kimball, G. Hoogenboom, S. Evett, A. Chanzy, S. Garrigues, A. Olioso, K.S. Copeland, J.L. Steiner, D. Cammarano, Y. Chen, M. Crépeau, E. Diamantopoulos, R. Ferrise, L. ManceauT. Gaiser, Y. Gao, S. Gayler, J.R. Guarin, T. Hunt, G. Jégo, G. Padovan, E. Pattey, D. Ripoche, A. Rodríguez, M. Ruiz-Ramos, V. Shelia, A.K. Srivastava, I. Supit, F. Tao, K. Thorp, M. Viswanathan, T. Weber, J. White

^*Corresponding author for this work

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

2 Citations (Scopus)

Abstract

Under climate change and increasingly extreme weather, projections of water demand and drought stress from process-based crop models can inform risk management and adaptation strategies. Previous studies investigating maize crop models demonstrated considerable error in the simulation of water use, and no similar evaluation of wheat crop models exists. The aims of this study were to (1) evaluate wheat crop models’ performance in reproducing observed daily evapotranspiration (ET) for Mediterranean and semi-arid environments, and (2) identify factors and processes associated with model error and uncertainty. These were assessed with an ensemble of wheat crop models for two experiments, one conducted in Bushland, Texas, USA (three seasons, deficit and full irrigation) and another in Avignon, France (four rainfed seasons) with winter bread and durum wheat, respectively. Models were calibrated with all observed data for crop growth. The model ensemble median underestimated water use in all environments evaluated, suggesting a systematic bias. The relative error in underestimating daily ET was constant across levels of atmospheric evaporative demand; therefore, the absolute error was greater for days with larger evaporative demand. This implies errors in the soil water balance increase more rapidly under high evaporative demand conditions. Using a potential versus reference crop evapotranspiration approach did not explain relative model performance. However, the sensitivity analysis indicated that simulation of atmospheric evaporative demand terms explained much more uncertainty in seasonal water use than terms related to soil depth or root growth. Errors in simulated leaf area index were associated with errors in daily simulated ET, but the relationship varied with the growth stage. Collectively, the results suggest the need to improve simulation of atmospheric ET demand to avoid underestimating projected impacts of drought or required water resource availability for viable production systems.

Original language	English
Article number	110032
Number of pages	18
Journal	Field Crops Research
Volume	332
DOIs	https://doi.org/10.1016/j.fcr.2025.110032
Publication status	Published - 1 Oct 2025

Keywords

Climate risk
Crop models
Drought stress
Evapotranspiration
Wheat

UN SDGs

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

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https://edepot.wur.nl/696549Licence: CC BY

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Webber, H., Cooke, D., Wang, C., Asseng, S., Martre, P., Ewert, F., Kimball, B., Hoogenboom, G., Evett, S., Chanzy, A., Garrigues, S., Olioso, A., Copeland, K. S., Steiner, J. L., Cammarano, D., Chen, Y., Crépeau, M., Diamantopoulos, E., Ferrise, R., ... White, J. (2025). Wheat crop models underestimate drought stress in semi-arid and Mediterranean environments. Field Crops Research, 332, Article 110032. https://doi.org/10.1016/j.fcr.2025.110032

@article{b90623a4088e482399e897bd03e90fef,

title = "Wheat crop models underestimate drought stress in semi-arid and Mediterranean environments",

abstract = "Under climate change and increasingly extreme weather, projections of water demand and drought stress from process-based crop models can inform risk management and adaptation strategies. Previous studies investigating maize crop models demonstrated considerable error in the simulation of water use, and no similar evaluation of wheat crop models exists. The aims of this study were to (1) evaluate wheat crop models{\textquoteright} performance in reproducing observed daily evapotranspiration (ET) for Mediterranean and semi-arid environments, and (2) identify factors and processes associated with model error and uncertainty. These were assessed with an ensemble of wheat crop models for two experiments, one conducted in Bushland, Texas, USA (three seasons, deficit and full irrigation) and another in Avignon, France (four rainfed seasons) with winter bread and durum wheat, respectively. Models were calibrated with all observed data for crop growth. The model ensemble median underestimated water use in all environments evaluated, suggesting a systematic bias. The relative error in underestimating daily ET was constant across levels of atmospheric evaporative demand; therefore, the absolute error was greater for days with larger evaporative demand. This implies errors in the soil water balance increase more rapidly under high evaporative demand conditions. Using a potential versus reference crop evapotranspiration approach did not explain relative model performance. However, the sensitivity analysis indicated that simulation of atmospheric evaporative demand terms explained much more uncertainty in seasonal water use than terms related to soil depth or root growth. Errors in simulated leaf area index were associated with errors in daily simulated ET, but the relationship varied with the growth stage. Collectively, the results suggest the need to improve simulation of atmospheric ET demand to avoid underestimating projected impacts of drought or required water resource availability for viable production systems.",

keywords = "Climate risk, Crop models, Drought stress, Evapotranspiration, Wheat",

author = "H. Webber and D. Cooke and C. Wang and S. Asseng and P. Martre and F. Ewert and B. Kimball and G. Hoogenboom and S. Evett and A. Chanzy and S. Garrigues and A. Olioso and K.S. Copeland and J.L. Steiner and D. Cammarano and Y. Chen and M. Cr{\'e}peau and E. Diamantopoulos and R. Ferrise and L. Manceau and T. Gaiser and Y. Gao and S. Gayler and J.R. Guarin and T. Hunt and G. J{\'e}go and G. Padovan and E. Pattey and D. Ripoche and A. Rodr{\'i}guez and M. Ruiz-Ramos and V. Shelia and A.K. Srivastava and I. Supit and F. Tao and K. Thorp and M. Viswanathan and T. Weber and J. White",

year = "2025",

month = oct,

day = "1",

doi = "10.1016/j.fcr.2025.110032",

language = "English",

volume = "332",

journal = "Field Crops Research",

issn = "0378-4290",

publisher = "Elsevier",

}

Webber, H, Cooke, D, Wang, C, Asseng, S, Martre, P, Ewert, F, Kimball, B, Hoogenboom, G, Evett, S, Chanzy, A, Garrigues, S, Olioso, A, Copeland, KS, Steiner, JL, Cammarano, D, Chen, Y, Crépeau, M, Diamantopoulos, E, Ferrise, R, Manceau, L, Gaiser, T, Gao, Y, Gayler, S, Guarin, JR, Hunt, T, Jégo, G, Padovan, G, Pattey, E, Ripoche, D, Rodríguez, A, Ruiz-Ramos, M, Shelia, V, Srivastava, AK, Supit, I, Tao, F, Thorp, K, Viswanathan, M, Weber, T & White, J 2025, 'Wheat crop models underestimate drought stress in semi-arid and Mediterranean environments', Field Crops Research, vol. 332, 110032. https://doi.org/10.1016/j.fcr.2025.110032

TY - JOUR

T1 - Wheat crop models underestimate drought stress in semi-arid and Mediterranean environments

AU - Webber, H.

AU - Cooke, D.

AU - Wang, C.

AU - Asseng, S.

AU - Martre, P.

AU - Ewert, F.

AU - Kimball, B.

AU - Hoogenboom, G.

AU - Evett, S.

AU - Chanzy, A.

AU - Garrigues, S.

AU - Olioso, A.

AU - Copeland, K.S.

AU - Steiner, J.L.

AU - Cammarano, D.

AU - Chen, Y.

AU - Crépeau, M.

AU - Diamantopoulos, E.

AU - Ferrise, R.

AU - Manceau, L.

AU - Gaiser, T.

AU - Gao, Y.

AU - Gayler, S.

AU - Guarin, J.R.

AU - Hunt, T.

AU - Jégo, G.

AU - Padovan, G.

AU - Pattey, E.

AU - Ripoche, D.

AU - Rodríguez, A.

AU - Ruiz-Ramos, M.

AU - Shelia, V.

AU - Srivastava, A.K.

AU - Supit, I.

AU - Tao, F.

AU - Thorp, K.

AU - Viswanathan, M.

AU - Weber, T.

AU - White, J.

PY - 2025/10/1

Y1 - 2025/10/1

N2 - Under climate change and increasingly extreme weather, projections of water demand and drought stress from process-based crop models can inform risk management and adaptation strategies. Previous studies investigating maize crop models demonstrated considerable error in the simulation of water use, and no similar evaluation of wheat crop models exists. The aims of this study were to (1) evaluate wheat crop models’ performance in reproducing observed daily evapotranspiration (ET) for Mediterranean and semi-arid environments, and (2) identify factors and processes associated with model error and uncertainty. These were assessed with an ensemble of wheat crop models for two experiments, one conducted in Bushland, Texas, USA (three seasons, deficit and full irrigation) and another in Avignon, France (four rainfed seasons) with winter bread and durum wheat, respectively. Models were calibrated with all observed data for crop growth. The model ensemble median underestimated water use in all environments evaluated, suggesting a systematic bias. The relative error in underestimating daily ET was constant across levels of atmospheric evaporative demand; therefore, the absolute error was greater for days with larger evaporative demand. This implies errors in the soil water balance increase more rapidly under high evaporative demand conditions. Using a potential versus reference crop evapotranspiration approach did not explain relative model performance. However, the sensitivity analysis indicated that simulation of atmospheric evaporative demand terms explained much more uncertainty in seasonal water use than terms related to soil depth or root growth. Errors in simulated leaf area index were associated with errors in daily simulated ET, but the relationship varied with the growth stage. Collectively, the results suggest the need to improve simulation of atmospheric ET demand to avoid underestimating projected impacts of drought or required water resource availability for viable production systems.

AB - Under climate change and increasingly extreme weather, projections of water demand and drought stress from process-based crop models can inform risk management and adaptation strategies. Previous studies investigating maize crop models demonstrated considerable error in the simulation of water use, and no similar evaluation of wheat crop models exists. The aims of this study were to (1) evaluate wheat crop models’ performance in reproducing observed daily evapotranspiration (ET) for Mediterranean and semi-arid environments, and (2) identify factors and processes associated with model error and uncertainty. These were assessed with an ensemble of wheat crop models for two experiments, one conducted in Bushland, Texas, USA (three seasons, deficit and full irrigation) and another in Avignon, France (four rainfed seasons) with winter bread and durum wheat, respectively. Models were calibrated with all observed data for crop growth. The model ensemble median underestimated water use in all environments evaluated, suggesting a systematic bias. The relative error in underestimating daily ET was constant across levels of atmospheric evaporative demand; therefore, the absolute error was greater for days with larger evaporative demand. This implies errors in the soil water balance increase more rapidly under high evaporative demand conditions. Using a potential versus reference crop evapotranspiration approach did not explain relative model performance. However, the sensitivity analysis indicated that simulation of atmospheric evaporative demand terms explained much more uncertainty in seasonal water use than terms related to soil depth or root growth. Errors in simulated leaf area index were associated with errors in daily simulated ET, but the relationship varied with the growth stage. Collectively, the results suggest the need to improve simulation of atmospheric ET demand to avoid underestimating projected impacts of drought or required water resource availability for viable production systems.

KW - Climate risk

KW - Crop models

KW - Drought stress

KW - Evapotranspiration

KW - Wheat

U2 - 10.1016/j.fcr.2025.110032

DO - 10.1016/j.fcr.2025.110032

M3 - Article

AN - SCOPUS:105007908484

SN - 0378-4290

VL - 332

JO - Field Crops Research

JF - Field Crops Research

M1 - 110032

ER -

Wheat crop models underestimate drought stress in semi-arid and Mediterranean environments

Abstract

Keywords

UN SDGs

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