Impacts of irrigation expansion on moist-heat stress based on IRRMIP results

Yi Yao; Agnès Ducharne; Benjamin I. Cook; Steven J. De Hertog; Kjetil Schanke Aas; Pedro F. Arboleda-Obando; Jonathan Buzan; Jeanne Colin; Maya Costantini; Bertrand Decharme; David M. Lawrence; Peter Lawrence; L. Ruby Leung; Min Hui Lo; Narayanappa Devaraju; William R. Wieder; Ren Jie Wu; Tian Zhou; Jonas Jägermeyr; Sonali McDermid; Yadu Pokhrel; Maxwell Elling; Naota Hanasaki; Paul Muñoz; Larissa S. Nazarenko; Kedar Otta; Yusuke Satoh; Tokuta Yokohata; Lei Jin; Xuhui Wang; Vimal Mishra; Subimal Ghosh; Wim Thiery

doi:10.1038/s41467-025-56356-1

Impacts of irrigation expansion on moist-heat stress based on IRRMIP results

Yi Yao, Agnès Ducharne, Benjamin I. Cook, Steven J. De Hertog, Kjetil Schanke Aas, Pedro F. Arboleda-Obando, Jonathan Buzan, Jeanne Colin, Maya Costantini, Bertrand Decharme, David M. Lawrence, Peter Lawrence, L. Ruby Leung, Min Hui Lo, Narayanappa Devaraju, William R. Wieder, Ren Jie Wu, Tian Zhou, Jonas Jägermeyr, Sonali McDermidYadu Pokhrel, Maxwell Elling, Naota Hanasaki, Paul Muñoz, Larissa S. Nazarenko, Kedar Otta, Yusuke Satoh, Tokuta Yokohata, Lei Jin, Xuhui Wang, Vimal Mishra, Subimal Ghosh, Wim Thiery

Terrestrial Sciences

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6 Scopus citations

Abstract

Irrigation rapidly expanded during the 20^th century, affecting climate via water, energy, and biogeochemical changes. Previous assessments of these effects predominantly relied on a single Earth System Model, and therefore suffered from structural model uncertainties. Here we quantify the impacts of historical irrigation expansion on climate by analysing simulation results from six Earth system models participating in the Irrigation Model Intercomparison Project (IRRMIP). Results show that irrigation expansion causes a rapid increase in irrigation water withdrawal, which leads to less frequent 2-meter air temperature heat extremes across heavily irrigated areas (≥4 times less likely). However, due to the irrigation-induced increase in air humidity, the cooling effect of irrigation expansion on moist-heat stress is less pronounced or even reversed, depending on the heat stress metric. In summary, this study indicates that irrigation deployment is not an efficient adaptation measure to escalating human heat stress under climate change, calling for carefully dealing with the increased exposure of local people to moist-heat stress.

Original language	English
Article number	1045
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-56356-1
State	Published - Dec 2025

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Yao, Y., Ducharne, A., Cook, B. I., De Hertog, S. J., Aas, K. S., Arboleda-Obando, P. F., Buzan, J., Colin, J., Costantini, M., Decharme, B., Lawrence, D. M., Lawrence, P., Leung, L. R., Lo, M. H., Devaraju, N., Wieder, W. R., Wu, R. J., Zhou, T., Jägermeyr, J., ... Thiery, W. (2025). Impacts of irrigation expansion on moist-heat stress based on IRRMIP results. Nature Communications, 16(1), Article 1045. https://doi.org/10.1038/s41467-025-56356-1

@article{3cb44bd6bd3643359f9ae41a264cb09a,

title = "Impacts of irrigation expansion on moist-heat stress based on IRRMIP results",

abstract = "Irrigation rapidly expanded during the 20th century, affecting climate via water, energy, and biogeochemical changes. Previous assessments of these effects predominantly relied on a single Earth System Model, and therefore suffered from structural model uncertainties. Here we quantify the impacts of historical irrigation expansion on climate by analysing simulation results from six Earth system models participating in the Irrigation Model Intercomparison Project (IRRMIP). Results show that irrigation expansion causes a rapid increase in irrigation water withdrawal, which leads to less frequent 2-meter air temperature heat extremes across heavily irrigated areas (≥4 times less likely). However, due to the irrigation-induced increase in air humidity, the cooling effect of irrigation expansion on moist-heat stress is less pronounced or even reversed, depending on the heat stress metric. In summary, this study indicates that irrigation deployment is not an efficient adaptation measure to escalating human heat stress under climate change, calling for carefully dealing with the increased exposure of local people to moist-heat stress.",

author = "Yi Yao and Agn{\`e}s Ducharne and Cook, \{Benjamin I.\} and \{De Hertog\}, \{Steven J.\} and Aas, \{Kjetil Schanke\} and Arboleda-Obando, \{Pedro F.\} and Jonathan Buzan and Jeanne Colin and Maya Costantini and Bertrand Decharme and Lawrence, \{David M.\} and Peter Lawrence and Leung, \{L. Ruby\} and Lo, \{Min Hui\} and Narayanappa Devaraju and Wieder, \{William R.\} and Wu, \{Ren Jie\} and Tian Zhou and Jonas J{\"a}germeyr and Sonali McDermid and Yadu Pokhrel and Maxwell Elling and Naota Hanasaki and Paul Mu{\~n}oz and Nazarenko, \{Larissa S.\} and Kedar Otta and Yusuke Satoh and Tokuta Yokohata and Lei Jin and Xuhui Wang and Vimal Mishra and Subimal Ghosh and Wim Thiery",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = dec,

doi = "10.1038/s41467-025-56356-1",

language = "English",

volume = "16",

journal = "Nature Communications",

issn = "2041-1723",

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Yao, Y, Ducharne, A, Cook, BI, De Hertog, SJ, Aas, KS, Arboleda-Obando, PF, Buzan, J, Colin, J, Costantini, M, Decharme, B, Lawrence, DM , Lawrence, P, Leung, LR, Lo, MH, Devaraju, N, Wieder, WR, Wu, RJ, Zhou, T, Jägermeyr, J, McDermid, S, Pokhrel, Y, Elling, M, Hanasaki, N, Muñoz, P, Nazarenko, LS, Otta, K, Satoh, Y, Yokohata, T, Jin, L, Wang, X, Mishra, V, Ghosh, S & Thiery, W 2025, 'Impacts of irrigation expansion on moist-heat stress based on IRRMIP results', Nature Communications, vol. 16, no. 1, 1045. https://doi.org/10.1038/s41467-025-56356-1

TY - JOUR

T1 - Impacts of irrigation expansion on moist-heat stress based on IRRMIP results

AU - Yao, Yi

AU - Ducharne, Agnès

AU - Cook, Benjamin I.

AU - De Hertog, Steven J.

AU - Aas, Kjetil Schanke

AU - Arboleda-Obando, Pedro F.

AU - Buzan, Jonathan

AU - Colin, Jeanne

AU - Costantini, Maya

AU - Decharme, Bertrand

AU - Lawrence, David M.

AU - Lawrence, Peter

AU - Leung, L. Ruby

AU - Lo, Min Hui

AU - Devaraju, Narayanappa

AU - Wieder, William R.

AU - Wu, Ren Jie

AU - Zhou, Tian

AU - Jägermeyr, Jonas

AU - McDermid, Sonali

AU - Pokhrel, Yadu

AU - Elling, Maxwell

AU - Hanasaki, Naota

AU - Muñoz, Paul

AU - Nazarenko, Larissa S.

AU - Otta, Kedar

AU - Satoh, Yusuke

AU - Yokohata, Tokuta

AU - Jin, Lei

AU - Wang, Xuhui

AU - Mishra, Vimal

AU - Ghosh, Subimal

AU - Thiery, Wim

PY - 2025/12

Y1 - 2025/12

N2 - Irrigation rapidly expanded during the 20th century, affecting climate via water, energy, and biogeochemical changes. Previous assessments of these effects predominantly relied on a single Earth System Model, and therefore suffered from structural model uncertainties. Here we quantify the impacts of historical irrigation expansion on climate by analysing simulation results from six Earth system models participating in the Irrigation Model Intercomparison Project (IRRMIP). Results show that irrigation expansion causes a rapid increase in irrigation water withdrawal, which leads to less frequent 2-meter air temperature heat extremes across heavily irrigated areas (≥4 times less likely). However, due to the irrigation-induced increase in air humidity, the cooling effect of irrigation expansion on moist-heat stress is less pronounced or even reversed, depending on the heat stress metric. In summary, this study indicates that irrigation deployment is not an efficient adaptation measure to escalating human heat stress under climate change, calling for carefully dealing with the increased exposure of local people to moist-heat stress.

AB - Irrigation rapidly expanded during the 20th century, affecting climate via water, energy, and biogeochemical changes. Previous assessments of these effects predominantly relied on a single Earth System Model, and therefore suffered from structural model uncertainties. Here we quantify the impacts of historical irrigation expansion on climate by analysing simulation results from six Earth system models participating in the Irrigation Model Intercomparison Project (IRRMIP). Results show that irrigation expansion causes a rapid increase in irrigation water withdrawal, which leads to less frequent 2-meter air temperature heat extremes across heavily irrigated areas (≥4 times less likely). However, due to the irrigation-induced increase in air humidity, the cooling effect of irrigation expansion on moist-heat stress is less pronounced or even reversed, depending on the heat stress metric. In summary, this study indicates that irrigation deployment is not an efficient adaptation measure to escalating human heat stress under climate change, calling for carefully dealing with the increased exposure of local people to moist-heat stress.

UR - https://www.scopus.com/pages/publications/85217103978

U2 - 10.1038/s41467-025-56356-1

DO - 10.1038/s41467-025-56356-1

M3 - Article

C2 - 39865074

AN - SCOPUS:85217103978

SN - 2041-1723

VL - 16

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 1045

ER -

Impacts of irrigation expansion on moist-heat stress based on IRRMIP results

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