Insights into management and physiological determinants of lowest pod height in soybean

IF 2 3区农林科学 Q2 AGRONOMY Agronomy Journal Pub Date : 2024-10-05 DOI:10.1002/agj2.21702

Piebiep Goufo, Robert W. Kluver III, Aníbal Cerrudo, Seth L. Naeve

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Abstract

Harvest losses caused by the low height of the lowest pods (LPH) are a significant issue in soybean cultivation. Minimizing these losses requires identifying management, physiological, and agronomic factors that interactively modulate LPH. Four studies were conducted to examine the relationships among soybean LPH, node and internode features, and light quality under different management practices. These practices included population density (19, 31, and 43 plants m⁻²) and row width (equidistant, 25, 51, and 76 cm), relative maturity (maturity group [MG] 0.8, MG 2.1, and MG 2.8), mulch color (gray bare soil, red mulch, and white mulch), and timing of stand reduction (V1, R3, R4, and R5 growth stages). An increase in population density from 19 to 43 plants m⁻² led to an average increase in LPH of 28%, from 11.9 to 15.3 cm. LPH was not influenced by row width. Later maturing cultivars demonstrated the highest potential for enhancing LPH, with late AG2802 having a higher LPH (18.8 cm) than early AG0803 (12.4 cm). Data indicated that the elongation of internodes 10, 11, and 12, along with changes in the red to far-red light ratio beneath the canopy, plays a pivotal role in determining the location of the lowest pods. Moreover, LPH is established around the R3 growth stage. Nevertheless, further investigations are warranted to gain a better understanding of how these parameters, individually and collectively, influence LPH in soybean.

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大豆最低豆荚高度的管理和生理决定因素透视

最低豆荚高度过低（LPH）造成的收获损失是大豆种植中的一个重要问题。要最大限度地减少这些损失，就必须确定管理、生理和农艺因素对 LPH 的交互调节作用。有四项研究探讨了不同管理方法下大豆 LPH、节和节间特征以及光照质量之间的关系。这些管理方法包括种植密度（19、31 和 43 株 m-2）和行宽（等距、25、51 和 76 厘米）、相对成熟度（成熟度组 [MG] 0.8、MG 2.1 和 MG 2.8）、覆盖物颜色（灰色裸土、红色覆盖物和白色覆盖物）以及减少株数的时间（V1、R3、R4 和 R5 生长阶段）。植株密度从 19 株 m-2 增加到 43 株 m-2 可使 LPH 平均增加 28%，从 11.9 厘米增加到 15.3 厘米。LPH不受行宽的影响。晚熟品种在提高 LPH 方面潜力最大，晚熟 AG2802 的 LPH（18.8 厘米）高于早熟 AG0803（12.4 厘米）。数据表明，第 10、11 和 12 节间的伸长，以及冠层下红光与远红光比例的变化，在决定最低豆荚位置方面起着关键作用。此外，LPH 是在 R3 生长阶段左右形成的。然而，为了更好地了解这些参数是如何单独或共同影响大豆的 LPH 的，还需要进行进一步的研究。

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 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.