Optimization of sowing dates for enhanced rice yield: insights from field experiments in the middle and lower reaches of the Yangtze River, China.

IF 5.4 3区材料科学 Q2 CHEMISTRY, PHYSICAL

ACS Applied Energy Materials Pub Date : 2024-10-28 DOI:10.1186/s12870-024-05729-7

Yalan Ji, Youzun Xu, Xueyuan Sun, Muhammad Ahmad Hassan, Yongjin Zhou, Huawen Zou, Zhong Li

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引用次数: 0

Abstract

An efficacious strategy to adapt to climate change involves optimizing the planting season, a technique that has been extensively utilized to enhance the use of solar radiation and temperature resources in rice cultivation. Field experiments were executed in the middle and lower reaches of the Yangtze River, China, employing three distinct rice cultivars and seven disparate sowing periods spanning 2019 to 2021. The objective of assessing the impact of sowing date on apparent radiation use efficiency (RUE_A), accumulated temperature use efficiencies (TUE), and overall rice yield. Subsequent to the delay of sowing dates, the duration of the comprehensive growth period initially exhibited a declining trajectory before subsequently escalating, with the reduction predominantly ascribed to a decrease in the number of days preceding heading. Furthermore, there was a tendency for both the mean daily and effective cumulative solar radiation to decline over the course of the growing period. The yield of the three rice varieties demonstrated an initial surge, which was then followed by a subsequent decline in reaction to the delay of sowing dates. A correlation analysis disclosed that solar radiation and effective cumulative temperature (EAT) were the predominant elements impacting grain yield. The outcomes of the path analysis indicate that EAT exerts the most substantial influence on yield, succeeded by cumulative total solar radiation (TSR), while photothermal quotient (PTQ) demonstrates the least impact on yield. There was a significant positive correlation between EAT and cumulative TSR with spikelets per panicle (0.237** and 0.218**), grain filling (0.753** and 0.576**), and grain weight (0.339** and 0.359**), respectively. The findings of this study indicate that an increase in yield is facilitated when the EAT after heading exceeds 594.9 ℃, the EAT surpasses 2016.7 ℃, the cumulative TSR before heading is above 1548.7 MJ m^- 2, the cumulative TSR after heading is over 603.0 MJ m^- 2, and the cumulative total radiation throughout the entire growth period is more than 2151.8 MJ m^- 2. Furthermore, the most optimal sowing date, as identified by this study, is June 6. This study provides key insights into boosting rice productivity in the middle and lower reaches of the Yangtze River, China by analyzing the impact of temperature and solar radiation on yield and identifying optimal growth conditions. Clinical trial number Not applicable.

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优化播种期以提高水稻产量：中国长江中下游田间试验的启示。

适应气候变化的有效策略包括优化播种期，这一技术已被广泛用于提高水稻种植对太阳辐射和温度资源的利用。我们在中国长江中下游地区进行了田间试验，采用了三种不同的水稻栽培品种和七个不同的播种期，时间跨度为 2019 年至 2021 年。目的是评估播种期对表观辐射利用效率（RUEA）、累积温度利用效率（TUE）和水稻总产量的影响。播种日期推迟后，综合生长期的持续时间最初呈下降趋势，随后逐渐上升，下降的主要原因是打顶前的天数减少。此外，在生长期内，日平均太阳辐射和有效累积太阳辐射均呈下降趋势。三个水稻品种的产量最初都出现了猛增，但随后又因播种日期推迟而下降。相关分析表明，太阳辐射和有效积温（EAT）是影响谷物产量的主要因素。路径分析结果表明，有效积温对产量的影响最大，其次是累积太阳辐射总量（TSR），而光热商数（PTQ）对产量的影响最小。EAT 和累积太阳辐射总量分别与每穗（0.237** 和 0.218**）、籽粒饱满度（0.753** 和 0.576**）和粒重（0.339** 和 0.359**）呈显著正相关。研究结果表明，当打顶后 EAT 超过 594.9 ℃，EAT 超过 2016.7 ℃，打顶前累积 TSR 超过 1548.7 MJ m-2，打顶后累积 TSR 超过 603.0 MJ m-2，整个生长期累积总辐射超过 2151.8 MJ m-2，则有利于增产。此外，本研究确定的最佳播种日期是 6 月 6 日。这项研究通过分析温度和太阳辐射对产量的影响以及确定最佳生长条件，为提高中国长江中下游地区的水稻产量提供了重要启示。临床试验编号不适用。

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

ACS Applied Energy Materials Materials Science-Materials Chemistry

CiteScore

10.30

自引率

6.20%

发文量

1368

期刊介绍： ACS Applied Energy Materials is an interdisciplinary journal publishing original research covering all aspects of materials, engineering, chemistry, physics and biology relevant to energy conversion and storage. The journal is devoted to reports of new and original experimental and theoretical research of an applied nature that integrate knowledge in the areas of materials, engineering, physics, bioscience, and chemistry into important energy applications.