Soybean Yield Simulation and Sustainability Assessment Based on the DSSAT-CROPGRO-Soybean Model

Plants Pub Date : 2024-09-08 DOI:10.3390/plants13172525

Lei Zhang, Zhenxi Cao, Yang Gao, Weixiong Huang, Zhuanyun Si, Yuanhang Guo, Hongbo Wang, Xingpeng Wang

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Abstract

In order to ensure national grain and oil security, it is imperative to expand the soybean planting area in the Xinjiang region. However, the scarcity of water resources in southern Xinjiang, the relatively backward soybean planting technology, and the lack of a supporting irrigation system have negatively impacted soybean planting and yield. In 2022 and 2023, we conducted an experiment which included three irrigation amounts of 27 mm, 36 mm, and 45 mm and analyzed the changes in dry mass and yield. Additionally, we simulated the potential yield using the corrected DSSAT-CROPGRO-Soybean model and biomass based on the meteorological data from 1994 to 2023. The results demonstrated that the model was capable of accurately predicting soybean emergence (the relative root mean square error (nRMSE) = 0, the absolute relative error (ARE) = 0), flowering (nRMSE = 0, ARE = 2.78%), maturity (nRMSE = 0, ARE = 3.21%). The model demonstrated high levels of accuracy in predicting soybean biomass (R2 = 0.98, nRMSE = 20.50%, ARE = 20.63%), 0–80 cm soil water storage (R2 = 0.64, nRMSE = 7.78%, ARE = 3.24%), and yield (R2 = 0.81, nRMSE = 10.83%, ARE = 8.79%). The biomass of soybean plants increases with the increase in irrigation amount. The highest biomass of 63 mm is 9379.19 kg·hm−2. When the irrigation yield is 36–45 mm (p < 0.05), the maximum yield can reach 4984.73 kg·hm−2; the maximum efficiency of soybean irrigation water was 33–36 mm. In light of the impact of soybean yield and irrigation water use efficiency, the optimal irrigation amount for soybean cultivation in southern Xinjiang is estimated to be between 36 and 42 mm. The simulation results provide a theoretical foundation for soybean cultivation in southern Xinjiang.

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基于 DSSAT-CROPGRO 大豆模型的大豆产量模拟和可持续性评估

为确保国家粮油安全，扩大新疆地区大豆种植面积势在必行。然而，南疆水资源匮乏，大豆种植技术相对落后，缺乏配套的灌溉系统，对大豆的种植和产量产生了不利影响。2022 年和 2023 年，我们进行了包括 27 毫米、36 毫米和 45 毫米三种灌溉量的试验，分析了干质量和产量的变化。此外，我们还根据 1994 年至 2023 年的气象数据，利用经校正的 DSSAT-CROPGRO-Soybean 模型和生物量模拟了潜在产量。结果表明，该模型能够准确预测大豆的出苗（相对均方根误差 (nRMSE) = 0，绝对相对误差 (ARE) = 0）、开花（nRMSE = 0，ARE = 2.78%）和成熟（nRMSE = 0，ARE = 3.21%）。该模型在预测大豆生物量（R2 = 0.98，nRMSE = 20.50%，ARE = 20.63%）、0-80 厘米土壤储水量（R2 = 0.64，nRMSE = 7.78%，ARE = 3.24%）和产量（R2 = 0.81，nRMSE = 10.83%，ARE = 8.79%）方面表现出较高的准确性。大豆植株的生物量随灌溉量的增加而增加。灌溉量为 63 毫米时，生物量最高，为 9379.19 kg-hm-2。当灌溉量为 36-45 mm 时（p < 0.05），最高产量可达 4984.73 kg-hm-2；大豆灌溉水的最大效率为 33-36 mm。根据大豆产量和灌溉水利用效率的影响，南疆大豆种植的最佳灌水量估计在 36-42 mm 之间。模拟结果为南疆大豆种植提供了理论依据。

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Plants

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