Improving wheat nitrogen use efficiency through a management zone-based optimization strategy by integrating crop model and remote sensing

IF 6.4 1区农林科学 Q1 AGRONOMY

Field Crops Research Pub Date : 2025-08-01 DOI:10.1016/j.fcr.2025.110088

Yue Li , Xiaotong Chen , Yuxin Miao , Xiaojun Liu , Yongchao Tian , Yan Zhu , Qiang Cao , Weixing Cao

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引用次数: 0

Abstract

Context

Precision nitrogen (N) management (PNM) is gaining attention for its ability to optimize wheat N use efficiency while reducing environmental impacts. Although both remote sensing platforms and crop modeling have been widely explored as key tools for PNM, limited research has integrated these approaches to dynamically optimize both basal and topdressing N rates on a large scale.

Objective

This study aimed to 1) estimate site- and season-specific target yields and basal N rates; 2) develop a new topdressing N strategy based on management zones (MZs) by integrating crop models with remote sensing data at the regional scale; and 3) evaluate its effectiveness in comparison with farmers’ conventional management (FCM) and the economic optimal N rate (EONR) strategies.

Methods

To achieve these objectives, county-level wheat yield data, vegetation indices, and a sustainable environmental index from Jiangsu Province were used to establish Random Forest (RF) and Quantile Random Forest models for estimating site- and season-specific target yields and basal N rates. MZs were delineated based on regional environmental heterogeneity, serving both for model calibration and determining the leaf area index (LAI) through remote sensing imagery. The WheatGrow model, calibrated by adjusting genetic coefficients, was employed to simulate wheat yield and phenology, showing strong potential for accurate simulation. Topdressing N rates were determined by calculating the LAI difference at the booting stage between topdressing and no-topdressing conditions, using a weather data fusion method. Field validation trials were conducted during the 2022–2023 wheat growing season across four MZs in Jiangsu Province.

Results

The results demonstrated that the RF model performed the best in yield prediction (R² = 0.94–0.95) and target yield determination. Higher target yields were observed in regions where the N recommendations were higher. Approximately 75 % of the N recommendations from the proposed PNM strategy were within 20 % of the measured EONR values. Field trials further revealed that the proposed PNM strategy improved partial factor productivity by 26–58 % compared to the FCM strategy while maintaining comparable yields and economic benefits.

Conclusion

In conclusion, the proposed PNM strategy offers a promising and scalable tool for variable-rate fertilization, with significant potential to enhance N use efficiency and promote sustainable agricultural development on a regional scale.

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基于作物模型与遥感相结合的管理区优化策略提高小麦氮素利用效率

精细氮素管理（PNM）因其在优化小麦氮素利用效率的同时减少对环境的影响而受到关注。虽然遥感平台和作物建模作为PNM的关键工具已经被广泛探索，但很少有研究将这些方法结合起来，在大范围内动态优化基肥和追肥氮素水平。本研究旨在1)估算不同地点和季节的目标产量和基础施氮量；2)在区域尺度上将作物模型与遥感数据相结合，建立基于管理区域（MZs）的追肥策略；3)与农户传统管理（FCM）和经济最优氮肥（EONR）策略进行比较，评价其有效性。方法利用江苏省县域小麦产量数据、植被指数和可持续环境指数建立随机森林（RF）和分位数随机森林模型，估算不同立地和季节的目标产量和基础氮素水平。基于区域环境异质性划分mz，既可用于模式定标，又可通过遥感影像确定叶面积指数（LAI）。采用WheatGrow模型，通过调整遗传系数进行校正，对小麦产量和物候进行模拟，显示出较强的准确模拟潜力。利用气象数据融合方法，计算孕穗期追肥与不追肥条件下的LAI差值，确定追肥N率。于2022-2023年小麦生长季在江苏省4个区域进行了田间验证试验。结果RF模型在产量预测（R²= 0.94 ~ 0.95）和目标产量确定方面具有较好的效果。在建议施氮量较高的地区，观察到较高的目标产量。在拟议的PNM策略中，大约75% %的N建议值与测量的EONR值的差距在20% %以内。田间试验进一步表明，与FCM策略相比，PNM策略将部分要素生产率提高了26-58 %，同时保持了相当的产量和经济效益。综上所述，PNM策略在提高氮素利用效率和促进区域农业可持续发展方面具有重要的应用潜力。

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

Field Crops Research 农林科学-农艺学

CiteScore

9.60

自引率

12.10%

发文量

307

审稿时长

46 days

期刊介绍： Field Crops Research is an international journal publishing scientific articles on: √ experimental and modelling research at field, farm and landscape levels on temperate and tropical crops and cropping systems, with a focus on crop ecology and physiology, agronomy, and plant genetics and breeding.