AquaCrop model-based sensitivity analysis of soil salinity dynamics and productivity under climate change in sandy-layered farmland

IF 5.9 1区农林科学 Q1 AGRONOMY

Agricultural Water Management Pub Date : 2025-02-01 DOI:10.1016/j.agwat.2024.109244

Zhuangzhuang Feng , Qingfeng Miao , Haibin Shi , José Manuel Gonçalves , Xianyue Li , Weiying Feng , Jianwen Yan , Dandan Yu , Yan Yan

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Abstract

To improve the simulation accuracy and efficiency of crop water models in semi-arid regions and considering climate change, we conducted a sensitivity analysis of the AquaCrop model crop parameters for maize (Zea mays) based on field monitoring data from 2020 to 2021 in the Hetao Irrigation District, China. We simulated soil water and salt dynamics, crop growth, water consumption, and final yield under climate change conditions. Non-conservative parameters, such as the crop growth coefficient (CGC) and maximum effective rooting depth (Z_x), significantly influenced soil water content and salt profile sensitivity. Z_x was highly sensitive to soil salt content. For maize biomass and yield, maximum canopy cover (CC_x) and CGC consistently showed high sensitivity. The standard crop transpiration coefficient (K_cTr,x) had a significant impact on yield. Water productivity (WP_ET) and harvest index (HI) were mainly sensitive to CC_x, K_cTr,x, normalized water productivity (WP*), and reference HI (HI₀). The model simulations, calibrated with these sensitive parameters, indicated that under future climate change scenarios, maize yield is projected to increase by approximately 19 % by mid-21st century due to elevated CO₂ concentrations and water productivity increasing by 22–27 %. Soil salinity is expected to rise by 0.2 t ha⁻¹ under high-emission scenarios, indicating that the challenge of soil salinization will become more severe. This study provides scientific evidence for developing agricultural management strategies to adapt to climate change, with the aim of enhancing crop yield and water-use efficiency, thus promoting sustainable agricultural development.

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气候变化下基于AquaCrop模型的沙质层状农田土壤盐分动态与生产力敏感性分析

为提高半干旱区作物水分模型的模拟精度和效率，并考虑气候变化因素，基于河套灌区2020 - 2021年的田间监测数据，对AquaCrop模型玉米作物参数进行敏感性分析。我们模拟了气候变化条件下的土壤水盐动态、作物生长、水分消耗和最终产量。作物生长系数（CGC）和最大有效生根深度（Zx）等非保守参数显著影响土壤含水量和盐剖面敏感性。Zx对土壤含盐量高度敏感。对于玉米生物量和产量，最大冠层盖度（CCx）和最大冠层盖度（CGC）均表现出较高的敏感性。标准作物蒸腾系数（KcTr,x）对产量有显著影响。水分生产力（WPET）和收获指数（HI）主要对CCx、KcTr、x、标准化水分生产力（WP*）和参考水分生产力（HI0）敏感。利用这些敏感参数校准的模型模拟结果表明，在未来气候变化情景下，由于二氧化碳浓度升高，预计到21世纪中叶玉米产量将增加约19% %，水分生产力将增加22 - 27% %。在高排放情景下，预计土壤盐度将上升0.2 t ha−1，表明土壤盐渍化的挑战将更加严峻。该研究为制定适应气候变化的农业管理策略提供了科学依据，旨在提高作物产量和水分利用效率，从而促进农业可持续发展。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Agricultural Water Management 农林科学-农艺学

CiteScore

12.10

自引率

14.90%

发文量

648

审稿时长

4.9 months

期刊介绍： Agricultural Water Management publishes papers of international significance relating to the science, economics, and policy of agricultural water management. In all cases, manuscripts must address implications and provide insight regarding agricultural water management.