Delta产量预测了美国玉米生产系统对氮肥的需求

IF 2 3区农林科学 Q2 AGRONOMY

Agronomy Journal Pub Date : 2025-09-05 DOI:10.1002/agj2.70150

Raziel A. Ordóñez, Charles M. White, John T. Spargo, Jason P. Kaye, Matthew Ruark, Javed Iqbal, Charles A. Shapiro, Wade E. Thomason, Nicole M. Fiorellino, Louis A. Thorne, Amy Shober, John H. Grove, Sarah M. Hirsh, Ray R. Weil, Michael J. Castellano, Sotirios V. Archontoulis, Jerry J. Hatfield, Chad D. Lee, Daniel J. Quinn, Zachary P. Sanders, Zoelie Rivera-Ocasio, Sarah Tierney, Kathleen E. Arrington, Andrew M. Lefever, Mauricio Tejera-Nieves, Gerasimos G. Danalatos, Laila A. Puntel, Hanna Poffenbarger, Sam Leuthold, Jarrod Miller, Gurpal S. Toor, Tony J. Vyn

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引用次数: 0

摘要

作物氮肥需求预测是当代农业面临的主要挑战。尽管目前的氮肥推荐工具取得了成功，但对农业氮污染的环境担忧，以及采用具有提高氮肥效率的改良玉米（Zea mays L.）技术，突出了对更精确的氮肥推荐系统的需求。在这里，我们的目标是开发一种基于增量产量（dY =最大产量-未施肥产量）预测玉米氮需求的方法。为了开发这个基于delta产量的氮肥（dY-based N）工具，我们选择了486个二次高原玉米产量对氮曲线的响应（来自美国北部的732个氮肥试验）来计算达到产量平台（Nx）所需的dY和N肥。采用不同的肥料与作物价格比（PR），计算了经济上的最适氮肥用量。然后将响应曲线输出分为校准集和验证集。利用标定集选择线性模型，以dY为基础预测Nx，得到9个州、农业生态系统区域和灌溉特定子模型。这些子模型预测验证集的Nx，平均绝对误差（MAE）为33.0 kg N ha−1。场地年二次高原响应拟合的预测值被用来改进进一步的预测结果。基于dY的EONR预测的MAE低于Nx的预测，根据PR的不同，其范围在19.9 ~ 25.4 kg N ha - 1之间，突出了系统的预测能力。在我们提出的基于日的方法中，排除了无响应和线性响应的试验，使未来的模型改进能够在更大范围内提高EONR对肥氮水平的预测精度。该系统整合了经济和农艺投入（包括管理、环境对土壤氮素供应的影响和最大产量），有助于减少氮素损失，并为氮素优化提供功能效益。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Delta yield predicts nitrogen fertilizer requirements for corn in US production systems

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Delta yield predicts nitrogen fertilizer requirements for corn in US production systems

Predicting crop nitrogen (N) fertilizer needs is a major challenge in contemporary agriculture. Despite the success of current N recommendation tools, environmental concerns over N pollution from agriculture, and the adoption of improved corn (Zea mays L.) technologies with enhanced N efficiencies highlight the need for more accurate N fertilizer recommendation systems. Here, we aimed to develop a methodology to predict corn N requirements based on delta yield (dY = maximum yield−unfertilized yield). To develop this delta yield-based nitrogen (dY-based N) tool, we selected 486 quadratic-plateau corn yield response to N curves (from 732 N rate trials across northern US) to calculate dY and N fertilizer required to reach the yield plateau (N_x). The economic optimum nitrogen rate (EONR) was calculated using different fertilizer:crop price ratios (PR). The response curve outputs were then partitioned into calibration and validation sets. The calibration set was used to select linear models to predict N_x based on dY, resulting in nine state, agroecosystem region, and irrigation-specific sub-models. These sub-models predicted N_x of the validation set with a mean absolute error (MAE) of 33.0 kg N ha⁻¹. Predicted values from the site-year quadratic-plateau response fits were used to improve further predictions’ outcomes. Predictions of EONR based on dY had a lower MAE than the predictions of N_x, ranging between 19.9 and 25.4 kg N ha⁻¹ depending on the PR, highlighting the system's predictive power. The exclusion of non-responsive and linear-response trials in our proposed dY-based approach enables future model refinement to improve EONR prediction accuracy across a broader range of yield responses to fertilizer-N rates. The proposed dY-based N system, which integrates both economic and agronomic inputs (including management, environmental effects on soil N supply, and maximum yields), could help to reduce N losses and provide functional benefits for N optimization.

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来源期刊

Agronomy Journal 农林科学-农艺学

CiteScore

4.70

自引率

9.50%

发文量

265

审稿时长

4.8 months

期刊介绍： After critical review and approval by the editorial board, AJ publishes articles reporting research findings in soil–plant relationships; crop science; soil science; biometry; crop, soil, pasture, and range management; crop, forage, and pasture production and utilization; turfgrass; agroclimatology; agronomic models; integrated pest management; integrated agricultural systems; and various aspects of entomology, weed science, animal science, plant pathology, and agricultural economics as applied to production agriculture. Notes are published about apparatus, observations, and experimental techniques. Observations usually are limited to studies and reports of unrepeatable phenomena or other unique circumstances. Review and interpretation papers are also published, subject to standard review. Contributions to the Forum section deal with current agronomic issues and questions in brief, thought-provoking form. Such papers are reviewed by the editor in consultation with the editorial board.