Improving the sustainability of arable cropping systems by modifying root traits: A modelling study for winter wheat

• Published in: European journal of soil science Vol. 75; no. 4
• Main Authors: Coucheney, Elsa, Kätterer, Thomas, Meurer, Katharina H. E., Jarvis, Nicholas
• Format: Journal Article
• Language: English
• Published: Oxford, UK Blackwell Publishing Ltd 01.07.2024; Wiley Subscription Services, Inc
• Subjects: Agricultural production; Arable land; Clay; Clay soils; Crop growth; Crop yield; Cropping systems; Dry matter; Dynamic structural analysis; Grain; Growing season; Growth models; Identification methods; ideotype; Markvetenskap; Microorganisms; Moisture content; Monoculture; Organic matter; Organic soils; Parameter identification; Parameter modification; Phenotypes; Physics; Plant breeding; Plant protection; root systems; Roots; Soil; Soil analysis; Soil improvement; Soil investigations; Soil organic matter; Soil profiles; Soil properties; Soil quality; Soil Science; Soil structure; Soil water; soil‐crop model; Structure-function relationships; Surface runoff; Sustainability; Transpiration; Triticum aestivum; Water balance; Water flow; Water uptake; Wheat; Winter; Winter wheat
• ISSN: 1351-0754; 1365-2389; 1365-2389
• DOI: 10.1111/ejss.13524

Modifying root systems by crop breeding has been attracting increasing attention as a potentially effective strategy to enhance the sustainability of agriculture by increasing soil organic matter (SOM) stocks and soil quality, whilst maintaining or even improving yields. We used the new soil‐crop model USSF (Uppsala model of Soil Structure and Function) to investigate the potential of this management strategy using winter wheat as a model crop. USSF combines a simple (generic) crop growth model with physics‐based descriptions of soil water flow, water uptake and transpiration by plants. It also includes a model of the interactions between soil structure dynamics and organic matter turnover that considers the effects of physical protection and microbial priming on the decomposition of SOM. The model was first calibrated against field data on soil water contents and both above‐ground and root biomass of winter wheat measured during one growing season in a clay soil in Uppsala, Sweden using the GLUE method to identify five ‘acceptable’ parameter sets. We created four model crops (ideotypes) by modifying root‐related parameters to mimic winter wheat phenotypes with improved root traits. Long‐term (30‐year) simulations of a conventionally tilled monoculture of winter wheat were then performed to evaluate the potential effects of cultivating these ideotypes on the soil water balance, soil organic matter stocks and grain yields. Our results showed that ideotypes with deeper root systems or root systems that are more effective for water uptake increased grain yields by 3% and SOM stocks in the soil profile by ca. 0.4%–0.5% in a 30‐year perspective (as an average of the five parameter sets). An ideotype in which below‐ground allocation of dry matter was increased at the expense of stem growth gave even larger increases in SOM stocks (ca. 1.4%). An ideotype combining all three modifications (deeper and more effective root systems and greater root production) showed even more promising results: compared with the baseline scenario, surface runoff decreased while yields were predicted to increase by ca. 7% and SOM stocks in the soil profile by ca. 2%, which is roughly equivalent to ca. 20% of the 4‐per‐mille target (https://4p1000.org/).