Field-scale modeling of root water uptake and crop growth in a tropical scenario

Modeling root water uptake (RWU) coupled with crop growth processes is crucial for optimizing water management in field crops, especially in tropical scenarios with high water demand. However, field-scale assessments of process-based RWU models are limited, as most efforts have focused on the root s...

Full description

Saved in:
Bibliographic Details
Published in:Field crops research 2025-03, Vol.322, p.109749, Article 109749
Main Authors: de Melo, Marina Luciana Abreu, de Jong van Lier, Quirijn, da Silva, Evandro Henrique Figueiredo Moura, Pereira, Rodolfo Armando de Almeida, van Dam, Jos C., Heinen, Marius, Marin, Fábio Ricardo
Format: Article
Language:English
Subjects:
Inverse modeling
Soil hydraulic properties
Transpiration mechanisms
Water productivity
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Modeling root water uptake (RWU) coupled with crop growth processes is crucial for optimizing water management in field crops, especially in tropical scenarios with high water demand. However, field-scale assessments of process-based RWU models are limited, as most efforts have focused on the root system scale, leading to few practical applications. To evaluate the performance of the SWAP agro-hydrological model in simulating and predicting crop growth, soil water balance components, and water transfer processes in the soil-plant-atmosphere continuum, using field observations and long-term simulation results of soybean and wheat cultivation in a tropical scenario. Measurements of crop growth variables, soil water content, and evapotranspiration were used to calibrate parameters related to crop growth, soil hydraulic properties, and RWU, and to evaluate the performance of the SWAP model in replicating three irrigated field experiments with soybean and wheat conducted in Brazil. Model performance was assessed using Root Mean Square Error (RMSE) and Nash-Sutcliffe Efficiency (NSE) statistics. After validation, long-term simulations (1978–2022) were performed to evaluate crop yield, irrigation requirements, and water productivity under a rainfed scenario and two irrigated scenarios with different irrigation triggering criteria. The SWAP model, incorporating a process-based RWU function (MFlux), effectively simulated crop growth, water use, and specific RWU mechanisms on a daily time step. After model calibration and evaluation, the RMSE values were ≤ 421 kg ha⁻¹ for grain yield, ≤ 0.029 cm³ cm⁻³ for soil water content, and ≤ 1.07 mm d⁻¹ for evapotranspiration, with mostly positive NSE values for all variables. Seasonal analyses of water management scenarios indicated that irrigation amounts were reduced by an average of 41 mm for wheat, while water productivity of irrigation increased by an average of 61 % for soybean when irrigation was triggered based on relative evapotranspiration instead of total available water depletion. The SWAP/MFlux model is suitable for simulating crop growth and soil-vegetation-atmosphere water transfer processes at the field scale in tropical soybean and wheat cultivation. Long-term analyses suggest that efficient water management, which maintains high crop yields while minimizing irrigation, depends on an irrigation criterion based on relative evapotranspiration. This study presents a process-based approach for predicting RWU coup
ISSN:0378-4290
DOI:10.1016/j.fcr.2025.109749