Crop models for future food systems

Rogério de S. Nóia-Júnior; Alex C. Ruane; Ioannis N. Athanasiadis; Frank Ewert; Matthew Tom Harrison; Jonas Jägermeyr; Pierre Martre; Christoph Müller; Taru Palosuo; Montserrat Salmerón; Heidi Webber; Dilys Sefakor Maccarthy; Senthold Asseng

doi:10.1016/j.oneear.2025.101487

Crop models for future food systems

Rogério de S. Nóia-Júnior
, Alex C. Ruane
, Ioannis N. Athanasiadis
, Frank Ewert
, Matthew Tom Harrison
, Jonas Jägermeyr
, Pierre Martre
, Christoph Müller
, Taru Palosuo
, Montserrat Salmerón
, Heidi Webber
, Dilys Sefakor Maccarthy
, Senthold Asseng

Soil and Irrigation Research Centre (SIREC)

Université Montpellier
NASA GISS
Wageningen University & Research
Leibniz Centre for Agricultural Landscape Research (ZALF)
University of Bonn
University of Tasmania
Center for Climate Systems Research
Member of the Leibniz Association
Natural Resources Institute Finland (Luke)
University of Kentucky
Brandenburg Technical University
Technical University of Munich

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

6 Citations (Scopus)

Abstract

Global food systems face intensifying pressure from climate change, resource scarcity, and rising demand, making their transformation toward resilience and sustainability urgent. Process-based crop growth models (CMs) are critical for understanding cropping system dynamics and supporting decisions from crop breeding to adaptive management across diverse environments. Yet, current CMs struggle to capture extreme events, novel production systems, and rapidly evolving data streams, limiting their ability to inform robust and timely decisions. Here, we outline CM structure, identify key knowledge gaps, and propose six priorities for next-generation CMs: (1) expand applications to extremes and to diverse systems; (2) support climate-resilient breeding; (3) integrate with machine learning for better inputs and forecasts; (4) link with standardized sensor and database networks; (5) promote modular, open-source architectures; and (6) build capacity in under-resourced regions. These priorities will substantially enhance CM robustness, comparability, and usability, reinforcing their role in guiding sustainable food system transformation.

Original language	English
Article number	101487
Journal	One Earth
Volume	8
Issue number	10
DOIs	https://doi.org/10.1016/j.oneear.2025.101487
Publication status	Published - 17 Oct 2025

UN SDGs

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

SDG 13 Climate Action

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10.1016/j.oneear.2025.101487

Cite this

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title = "Crop models for future food systems",

abstract = "Global food systems face intensifying pressure from climate change, resource scarcity, and rising demand, making their transformation toward resilience and sustainability urgent. Process-based crop growth models (CMs) are critical for understanding cropping system dynamics and supporting decisions from crop breeding to adaptive management across diverse environments. Yet, current CMs struggle to capture extreme events, novel production systems, and rapidly evolving data streams, limiting their ability to inform robust and timely decisions. Here, we outline CM structure, identify key knowledge gaps, and propose six priorities for next-generation CMs: (1) expand applications to extremes and to diverse systems; (2) support climate-resilient breeding; (3) integrate with machine learning for better inputs and forecasts; (4) link with standardized sensor and database networks; (5) promote modular, open-source architectures; and (6) build capacity in under-resourced regions. These priorities will substantially enhance CM robustness, comparability, and usability, reinforcing their role in guiding sustainable food system transformation.",

author = "N{\'o}ia-J{\'u}nior, \{Rog{\'e}rio de S.\} and Ruane, \{Alex C.\} and Athanasiadis, \{Ioannis N.\} and Frank Ewert and Harrison, \{Matthew Tom\} and Jonas J{\"a}germeyr and Pierre Martre and Christoph M{\"u}ller and Taru Palosuo and Montserrat Salmer{\'o}n and Heidi Webber and Maccarthy, \{Dilys Sefakor\} and Senthold Asseng",

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T1 - Crop models for future food systems

AU - Nóia-Júnior, Rogério de S.

AU - Ruane, Alex C.

AU - Athanasiadis, Ioannis N.

AU - Ewert, Frank

AU - Harrison, Matthew Tom

AU - Jägermeyr, Jonas

AU - Martre, Pierre

AU - Müller, Christoph

AU - Palosuo, Taru

AU - Salmerón, Montserrat

AU - Webber, Heidi

AU - Maccarthy, Dilys Sefakor

AU - Asseng, Senthold

PY - 2025/10/17

Y1 - 2025/10/17

N2 - Global food systems face intensifying pressure from climate change, resource scarcity, and rising demand, making their transformation toward resilience and sustainability urgent. Process-based crop growth models (CMs) are critical for understanding cropping system dynamics and supporting decisions from crop breeding to adaptive management across diverse environments. Yet, current CMs struggle to capture extreme events, novel production systems, and rapidly evolving data streams, limiting their ability to inform robust and timely decisions. Here, we outline CM structure, identify key knowledge gaps, and propose six priorities for next-generation CMs: (1) expand applications to extremes and to diverse systems; (2) support climate-resilient breeding; (3) integrate with machine learning for better inputs and forecasts; (4) link with standardized sensor and database networks; (5) promote modular, open-source architectures; and (6) build capacity in under-resourced regions. These priorities will substantially enhance CM robustness, comparability, and usability, reinforcing their role in guiding sustainable food system transformation.

AB - Global food systems face intensifying pressure from climate change, resource scarcity, and rising demand, making their transformation toward resilience and sustainability urgent. Process-based crop growth models (CMs) are critical for understanding cropping system dynamics and supporting decisions from crop breeding to adaptive management across diverse environments. Yet, current CMs struggle to capture extreme events, novel production systems, and rapidly evolving data streams, limiting their ability to inform robust and timely decisions. Here, we outline CM structure, identify key knowledge gaps, and propose six priorities for next-generation CMs: (1) expand applications to extremes and to diverse systems; (2) support climate-resilient breeding; (3) integrate with machine learning for better inputs and forecasts; (4) link with standardized sensor and database networks; (5) promote modular, open-source architectures; and (6) build capacity in under-resourced regions. These priorities will substantially enhance CM robustness, comparability, and usability, reinforcing their role in guiding sustainable food system transformation.

UR - https://www.scopus.com/pages/publications/105019777489

U2 - 10.1016/j.oneear.2025.101487

DO - 10.1016/j.oneear.2025.101487

M3 - Review article

AN - SCOPUS:105019777489

SN - 2590-3330

VL - 8

JO - One Earth

JF - One Earth

IS - 10

M1 - 101487

ER -

Crop models for future food systems

Abstract

UN SDGs

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