Sustainable intensification: time to question the goal of ever-increasing agricultural production

Gabriel Y.K. Moinet; Michiel H. in ’t Zandt; Jan Hassink; Johanna Schild; Rosa Boone; Henk Martens; Carmen Vazquez; Peter M. van Bodegom; Chenguang Gao; Nick van Eekeren; Marie J. Zwetsloot; Howard Koster; Marta Loreggian; Giulia Vultaggio; Deborah J. de Groot; Rachel E. Creamer

doi:10.1016/j.geoderma.2025.117555

Sustainable intensification: time to question the goal of ever-increasing agricultural production

Gabriel Y.K. Moinet
, Michiel H. in ’t Zandt
, Jan Hassink
, Johanna Schild
, Rosa Boone
, Henk Martens
, Carmen Vazquez
, Peter M. van Bodegom
, Chenguang Gao
, Nick van Eekeren
, Marie J. Zwetsloot
, Howard Koster
, Marta Loreggian
, Giulia Vultaggio
, Deborah J. de Groot
, Rachel E. Creamer

NIOO - Terrestrial Ecology (TE)

Research output: Contribution to journal/periodical › Article › Scientific › peer-review

2 Citations (Scopus)

Abstract

Soils play a pivotal role in agroecosystems by supporting multiple functions such as primary production, nutrient cycling, water regulation, climate regulation, and habitat for biodiversity. This study examines how land use intensity (LUI) affects soil multifunctionality in agricultural systems, with a focus on grasslands and croplands under conventional, organic and semi-natural management. Our approach uniquely combines detailed management information from commercial farms with a detailed assessment of multiple soil functions. By restricting the study to a narrow geographic area in the east of the Netherlands, we were able to isolate the effects of management from pedoclimatic variability, thus providing one of the first empirical tests of how LUI shapes multifunctionality under real farming conditions. Soil samples from 45 grasslands and 37 croplands were analysed. Soil functions were quantified using the Soil Navigator Decision Support System, and LUI was calculated from 11 management indicators for grasslands and croplands separately. Results showed that higher LUI improved primary production and nutrient cycling functions but negatively impacted climate regulation and habitat for biodiversity. Organic fields, defined here as those not receiving synthetic fertilisers or pest control, exhibited lower LUI, achieving better biodiversity and climate regulation but at a cost of productivity. Trade-offs were evident between primary production and biodiversity and climate regulation, while synergies were found between habitat for biodiversity and climate regulation. These findings emphasise the complexity of balancing soil functions at field scale, challenging claims that productivity can increase without trade-offs. We conclude that, rather than systematically aiming at intensifying production sustainably at field or farm scale, more attention should be given to balancing food availability with landscape management demands at regional to global scales.

Original language	English
Article number	117555
Journal	Geoderma
Volume	463
DOIs	https://doi.org/10.1016/j.geoderma.2025.117555
Publication status	Published - Nov 2025

Keywords

Land use intensity
Multifunctionality
Organic
Soil functions
Soil health
Synergy
Trade-off

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Moinet, G. Y. K., in ’t Zandt, M. H., Hassink, J., Schild, J., Boone, R., Martens, H., Vazquez, C., van Bodegom, P. M., Gao, C., van Eekeren, N., Zwetsloot, M. J., Koster, H., Loreggian, M., Vultaggio, G., de Groot, D. J., & Creamer, R. E. (2025). Sustainable intensification: time to question the goal of ever-increasing agricultural production. Geoderma, 463, Article 117555. https://doi.org/10.1016/j.geoderma.2025.117555

@article{24cf663f05b94fcd82fd8f046e447e96,

title = "Sustainable intensification: time to question the goal of ever-increasing agricultural production",

abstract = "Soils play a pivotal role in agroecosystems by supporting multiple functions such as primary production, nutrient cycling, water regulation, climate regulation, and habitat for biodiversity. This study examines how land use intensity (LUI) affects soil multifunctionality in agricultural systems, with a focus on grasslands and croplands under conventional, organic and semi-natural management. Our approach uniquely combines detailed management information from commercial farms with a detailed assessment of multiple soil functions. By restricting the study to a narrow geographic area in the east of the Netherlands, we were able to isolate the effects of management from pedoclimatic variability, thus providing one of the first empirical tests of how LUI shapes multifunctionality under real farming conditions. Soil samples from 45 grasslands and 37 croplands were analysed. Soil functions were quantified using the Soil Navigator Decision Support System, and LUI was calculated from 11 management indicators for grasslands and croplands separately. Results showed that higher LUI improved primary production and nutrient cycling functions but negatively impacted climate regulation and habitat for biodiversity. Organic fields, defined here as those not receiving synthetic fertilisers or pest control, exhibited lower LUI, achieving better biodiversity and climate regulation but at a cost of productivity. Trade-offs were evident between primary production and biodiversity and climate regulation, while synergies were found between habitat for biodiversity and climate regulation. These findings emphasise the complexity of balancing soil functions at field scale, challenging claims that productivity can increase without trade-offs. We conclude that, rather than systematically aiming at intensifying production sustainably at field or farm scale, more attention should be given to balancing food availability with landscape management demands at regional to global scales.",

keywords = "Land use intensity, Multifunctionality, Organic, Soil functions, Soil health, Synergy, Trade-off",

author = "Moinet, \{Gabriel Y.K.\} and \{in {\textquoteright}t Zandt\}, \{Michiel H.\} and Jan Hassink and Johanna Schild and Rosa Boone and Henk Martens and Carmen Vazquez and \{van Bodegom\}, \{Peter M.\} and Chenguang Gao and \{van Eekeren\}, Nick and Zwetsloot, \{Marie J.\} and Howard Koster and Marta Loreggian and Giulia Vultaggio and \{de Groot\}, \{Deborah J.\} and Creamer, \{Rachel E.\}",

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

year = "2025",

month = nov,

doi = "10.1016/j.geoderma.2025.117555",

language = "English",

volume = "463",

journal = "Geoderma",

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Moinet, GYK, in ’t Zandt, MH, Hassink, J, Schild, J, Boone, R, Martens, H, Vazquez, C, van Bodegom, PM, Gao, C, van Eekeren, N, Zwetsloot, MJ, Koster, H, Loreggian, M, Vultaggio, G, de Groot, DJ & Creamer, RE 2025, 'Sustainable intensification: time to question the goal of ever-increasing agricultural production', Geoderma, vol. 463, 117555. https://doi.org/10.1016/j.geoderma.2025.117555

TY - JOUR

T1 - Sustainable intensification

T2 - time to question the goal of ever-increasing agricultural production

AU - Moinet, Gabriel Y.K.

AU - in ’t Zandt, Michiel H.

AU - Hassink, Jan

AU - Schild, Johanna

AU - Boone, Rosa

AU - Martens, Henk

AU - Vazquez, Carmen

AU - van Bodegom, Peter M.

AU - Gao, Chenguang

AU - van Eekeren, Nick

AU - Zwetsloot, Marie J.

AU - Koster, Howard

AU - Loreggian, Marta

AU - Vultaggio, Giulia

AU - de Groot, Deborah J.

AU - Creamer, Rachel E.

PY - 2025/11

Y1 - 2025/11

N2 - Soils play a pivotal role in agroecosystems by supporting multiple functions such as primary production, nutrient cycling, water regulation, climate regulation, and habitat for biodiversity. This study examines how land use intensity (LUI) affects soil multifunctionality in agricultural systems, with a focus on grasslands and croplands under conventional, organic and semi-natural management. Our approach uniquely combines detailed management information from commercial farms with a detailed assessment of multiple soil functions. By restricting the study to a narrow geographic area in the east of the Netherlands, we were able to isolate the effects of management from pedoclimatic variability, thus providing one of the first empirical tests of how LUI shapes multifunctionality under real farming conditions. Soil samples from 45 grasslands and 37 croplands were analysed. Soil functions were quantified using the Soil Navigator Decision Support System, and LUI was calculated from 11 management indicators for grasslands and croplands separately. Results showed that higher LUI improved primary production and nutrient cycling functions but negatively impacted climate regulation and habitat for biodiversity. Organic fields, defined here as those not receiving synthetic fertilisers or pest control, exhibited lower LUI, achieving better biodiversity and climate regulation but at a cost of productivity. Trade-offs were evident between primary production and biodiversity and climate regulation, while synergies were found between habitat for biodiversity and climate regulation. These findings emphasise the complexity of balancing soil functions at field scale, challenging claims that productivity can increase without trade-offs. We conclude that, rather than systematically aiming at intensifying production sustainably at field or farm scale, more attention should be given to balancing food availability with landscape management demands at regional to global scales.

AB - Soils play a pivotal role in agroecosystems by supporting multiple functions such as primary production, nutrient cycling, water regulation, climate regulation, and habitat for biodiversity. This study examines how land use intensity (LUI) affects soil multifunctionality in agricultural systems, with a focus on grasslands and croplands under conventional, organic and semi-natural management. Our approach uniquely combines detailed management information from commercial farms with a detailed assessment of multiple soil functions. By restricting the study to a narrow geographic area in the east of the Netherlands, we were able to isolate the effects of management from pedoclimatic variability, thus providing one of the first empirical tests of how LUI shapes multifunctionality under real farming conditions. Soil samples from 45 grasslands and 37 croplands were analysed. Soil functions were quantified using the Soil Navigator Decision Support System, and LUI was calculated from 11 management indicators for grasslands and croplands separately. Results showed that higher LUI improved primary production and nutrient cycling functions but negatively impacted climate regulation and habitat for biodiversity. Organic fields, defined here as those not receiving synthetic fertilisers or pest control, exhibited lower LUI, achieving better biodiversity and climate regulation but at a cost of productivity. Trade-offs were evident between primary production and biodiversity and climate regulation, while synergies were found between habitat for biodiversity and climate regulation. These findings emphasise the complexity of balancing soil functions at field scale, challenging claims that productivity can increase without trade-offs. We conclude that, rather than systematically aiming at intensifying production sustainably at field or farm scale, more attention should be given to balancing food availability with landscape management demands at regional to global scales.

KW - Land use intensity

KW - Multifunctionality

KW - Organic

KW - Soil functions

KW - Soil health

KW - Synergy

KW - Trade-off

U2 - 10.1016/j.geoderma.2025.117555

DO - 10.1016/j.geoderma.2025.117555

M3 - Article

AN - SCOPUS:105018911393

SN - 0016-7061

VL - 463

JO - Geoderma

JF - Geoderma

M1 - 117555

ER -

Sustainable intensification: time to question the goal of ever-increasing agricultural production

Abstract

Keywords

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