Optimizing planting density for enhanced maize yield and resource use efficiency in China. A meta-analysis

IF 6.7 1区农林科学 Q1 AGRONOMY

Agronomy for Sustainable Development Pub Date : 2025-06-10 DOI:10.1007/s13593-025-01027-0

Miaomiao Zhang, Xiaoru Zhao, Xiaoqing Han, Yijie Chen, Pengfei Dang, Jiquan Xue, Xiaoliang Qin, Kadambot H. M. Siddique

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引用次数: 0

Abstract

Reasoned increases in planting density are key measures to enhance maize yields. However, most existing studies on maize planting density based on long time spans often fail to account for diverse microclimates. The impact of planting density on yield components has not also been well investigated in major production regions of China. Therefore, we conducted a meta-analysis of 1951 data pairs from 160 published papers (2013–2023) to assess the effects of increasing planting density on maize yield, yield components, phenotypic traits, and resource utilization and to determine optimal density increase ranges for different environments. The results showed that increasing planting density improved the leaf area index by 23.4%, plant height by 1.8%, aboveground dry matter accumulation by 15.9%, water use efficiency by 3.8%, nitrogen use efficiency and 34.2%, and grain yield by 10.0–11.0%. Dense planting also increased the maize ear number per area by 34.3% but decreased grain number per ear by 12.5%, 1000-grain weight by 7.2%, and harvest index by 2.4%. Notably, the density increase range emerged as the primary factor influencing yield and its components, with changes in grain number per ear the most significant contributor to yield variations. A 25–50% density increase range was identified as optimal, resulting in an 11.5–13.4% yield increase. Average local planting densities were 63,496 plants·ha^–1 in the Northwest, 58,928 plants·ha^–1 in the Huang-Huai-Hai region, 58,234 plants·ha^–1 in the Northeast, and 51,761 plants·ha^–1 in the Southwest. Here, we show for the first time that the optimal density increase range varied by region: 25–50% for the Northeast, >50% for the Huang-Huai-Hai and Southwest, and 0–25% for the Northwest. These findings highlight the importance of tailoring planting density to local conditions, offering a scientific basis for optimizing maize production across diverse regions in China.

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优化种植密度提高中国玉米产量和资源利用效率一个荟萃分析

合理提高种植密度是提高玉米产量的关键措施。然而，大多数基于长时间跨度的玉米种植密度研究往往不能考虑不同的小气候。在中国主要产区，种植密度对产量构成的影响也没有得到很好的研究。因此，我们对160篇已发表论文（2013-2023）的1951对数据进行了meta分析，以评估增加种植密度对玉米产量、产量构成、表型性状和资源利用的影响，并确定不同环境下的最佳密度增加范围。结果表明，增加种植密度可使叶片面积指数提高23.4%，株高提高1.8%，地上干物质积累提高15.9%，水分利用效率提高3.8%，氮利用效率提高34.2%，籽粒产量提高10.0 ~ 11.0%。密植使玉米单株穗数增加34.3%，穗粒数减少12.5%，千粒重减少7.2%，收获指数减少2.4%。密度增加幅度是影响产量及其构成因素的主要因素，单穗粒数的变化是影响产量变化的最显著因素。结果表明，25-50%的密度增加范围是最佳的，产量增加11.5-13.4%。西北地区平均种植密度为63496株·ha-1，黄淮海地区为58928株·ha-1，东北地区为58234株·ha-1，西南地区为51761株·ha-1。研究首次发现，东北地区的最优密度增长幅度为25-50%，黄淮海和西南地区为50%，西北地区为0-25%。这些发现突出了因地制宜地调整种植密度的重要性，为优化中国不同地区的玉米生产提供了科学依据。

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

Agronomy for Sustainable Development 农林科学-农艺学

CiteScore

10.70

自引率

8.20%

发文量

108

审稿时长

3 months

期刊介绍： Agronomy for Sustainable Development (ASD) is a peer-reviewed scientific journal of international scope, dedicated to publishing original research articles, review articles, and meta-analyses aimed at improving sustainability in agricultural and food systems. The journal serves as a bridge between agronomy, cropping, and farming system research and various other disciplines including ecology, genetics, economics, and social sciences. ASD encourages studies in agroecology, participatory research, and interdisciplinary approaches, with a focus on systems thinking applied at different scales from field to global levels. Research articles published in ASD should present significant scientific advancements compared to existing knowledge, within an international context. Review articles should critically evaluate emerging topics, and opinion papers may also be submitted as reviews. Meta-analysis articles should provide clear contributions to resolving widely debated scientific questions.