Global warming increases the risk of crop yield failures driven by climate oscillations

Linchao Li; Bin Wang; Puyu Feng; Chaoqun Lu; Jonas Jägermeyr; Senthold Asseng; Jing Jia Luo; Matthew Tom Harrison; Qinsi He; Ke Liu; De Li Liu; Yi Li; Hao Feng; Guijun Yang; Chunjiang Zhao; Kadambot H.M. Siddique; Hanqin Tian; Qiang Yu

doi:10.1016/j.oneear.2025.101318

Global warming increases the risk of crop yield failures driven by climate oscillations

Linchao Li
, Bin Wang
, Puyu Feng
, Chaoqun Lu
, Jonas Jägermeyr
, Senthold Asseng
, Jing Jia Luo
, Matthew Tom Harrison
, Qinsi He
, Ke Liu
, De Li Liu
, Yi Li
, Hao Feng
, Guijun Yang
, Chunjiang Zhao
, Kadambot H.M. Siddique
, Hanqin Tian
, Qiang Yu

Chair of Digital Agriculture

Inner Mongolia Agricultural University
Northwest A and F University
Iowa State University
Wagga Wagga Agricultural Institute
Hawkesbury Institute for the Environment
Graham Centre for Agricultural Innovation (an Alliance between NSW Department of Industry and Charles Sturt University)
China Agricultural University
NASA Goddard Institute for Space Studies
Center for Climate Systems Research
Member of the Leibniz Association
Nanjing University of Information Science & Technology
Tasmanian Institute of Agriculture
University of Technology Sydney
University of New South Wales
Chang'an University
Beijing Academy of Agriculture and Forestry Sciences
University of Western Australia
Boston College

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

4 Scopus citations

Abstract

Enhancing food-system resilience is critical in the face of increasing climate variability that threatens food security. Large-scale climate oscillations are key drivers of climate conditions that disrupt agricultural productivity. However, how such effects are shifting under greenhouse warming remains unclear. Here, we integrate machine learning with process-based crop models to quantify changes in climate-oscillation-driven yield variability under warming scenarios. We find that climate change increases the dominance of the North Atlantic Oscillation (NAO) in the Northern Hemisphere and the El Niño-Southern Oscillation (ENSO) in the Southern Hemisphere, exposing an additional 5.1%–12% of global croplands to climate oscillation shocks. Negative NAO and El Niño events are projected to cause simultaneous yield losses of 2.0%–8.4% across multiple breadbaskets, while opposite phases provide weaker benefits, indicating asymmetric impacts and greater food security risks. We highlight the importance of incorporating shifting teleconnections into early-warning systems and targeted adaptation strategies to enhance global food-system resilience.

Original language	English
Article number	101318
Journal	One Earth
Volume	8
Issue number	6
DOIs	https://doi.org/10.1016/j.oneear.2025.101318
State	Published - 20 Jun 2025

UN SDGs

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

SDG 2 Zero Hunger
SDG 13 Climate Action

Keywords

GCMs
climate oscillations
crop model
crop yield failure
dominant driver

Access to Document

10.1016/j.oneear.2025.101318

Cite this

Li, L., Wang, B., Feng, P., Lu, C., Jägermeyr, J., Asseng, S., Luo, J. J., Harrison, M. T., He, Q., Liu, K., Liu, D. L., Li, Y., Feng, H., Yang, G., Zhao, C., Siddique, K. H. M., Tian, H., & Yu, Q. (2025). Global warming increases the risk of crop yield failures driven by climate oscillations. One Earth, 8(6), Article 101318. https://doi.org/10.1016/j.oneear.2025.101318

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abstract = "Enhancing food-system resilience is critical in the face of increasing climate variability that threatens food security. Large-scale climate oscillations are key drivers of climate conditions that disrupt agricultural productivity. However, how such effects are shifting under greenhouse warming remains unclear. Here, we integrate machine learning with process-based crop models to quantify changes in climate-oscillation-driven yield variability under warming scenarios. We find that climate change increases the dominance of the North Atlantic Oscillation (NAO) in the Northern Hemisphere and the El Ni{\~n}o-Southern Oscillation (ENSO) in the Southern Hemisphere, exposing an additional 5.1\%–12\% of global croplands to climate oscillation shocks. Negative NAO and El Ni{\~n}o events are projected to cause simultaneous yield losses of 2.0\%–8.4\% across multiple breadbaskets, while opposite phases provide weaker benefits, indicating asymmetric impacts and greater food security risks. We highlight the importance of incorporating shifting teleconnections into early-warning systems and targeted adaptation strategies to enhance global food-system resilience.",

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AU - Asseng, Senthold

AU - Luo, Jing Jia

AU - Harrison, Matthew Tom

AU - He, Qinsi

AU - Liu, Ke

AU - Liu, De Li

AU - Li, Yi

AU - Feng, Hao

AU - Yang, Guijun

AU - Zhao, Chunjiang

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AU - Tian, Hanqin

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N2 - Enhancing food-system resilience is critical in the face of increasing climate variability that threatens food security. Large-scale climate oscillations are key drivers of climate conditions that disrupt agricultural productivity. However, how such effects are shifting under greenhouse warming remains unclear. Here, we integrate machine learning with process-based crop models to quantify changes in climate-oscillation-driven yield variability under warming scenarios. We find that climate change increases the dominance of the North Atlantic Oscillation (NAO) in the Northern Hemisphere and the El Niño-Southern Oscillation (ENSO) in the Southern Hemisphere, exposing an additional 5.1%–12% of global croplands to climate oscillation shocks. Negative NAO and El Niño events are projected to cause simultaneous yield losses of 2.0%–8.4% across multiple breadbaskets, while opposite phases provide weaker benefits, indicating asymmetric impacts and greater food security risks. We highlight the importance of incorporating shifting teleconnections into early-warning systems and targeted adaptation strategies to enhance global food-system resilience.

AB - Enhancing food-system resilience is critical in the face of increasing climate variability that threatens food security. Large-scale climate oscillations are key drivers of climate conditions that disrupt agricultural productivity. However, how such effects are shifting under greenhouse warming remains unclear. Here, we integrate machine learning with process-based crop models to quantify changes in climate-oscillation-driven yield variability under warming scenarios. We find that climate change increases the dominance of the North Atlantic Oscillation (NAO) in the Northern Hemisphere and the El Niño-Southern Oscillation (ENSO) in the Southern Hemisphere, exposing an additional 5.1%–12% of global croplands to climate oscillation shocks. Negative NAO and El Niño events are projected to cause simultaneous yield losses of 2.0%–8.4% across multiple breadbaskets, while opposite phases provide weaker benefits, indicating asymmetric impacts and greater food security risks. We highlight the importance of incorporating shifting teleconnections into early-warning systems and targeted adaptation strategies to enhance global food-system resilience.

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KW - dominant driver

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Global warming increases the risk of crop yield failures driven by climate oscillations

Abstract

UN SDGs

Keywords

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