额外投入有机肥料和菌肥可调节大豆根系结构和干物质分配，从而在中国半干旱地区实现可持续产量。

Additional organic and bacterium fertilizer input regulated soybean root architecture and dry matter distribution for a sustainable yield in the semi-arid Region of China.

作者信息

Liu Yu, Liu Chuhua, Wei Lichao, Zhang Xudong, Liu Qinhui, Bai Jiling, Wang Xiaolin, Zhang Suiqi

机构信息

College of Life Sciences, Yulin University, Yulin, China.

Engineering and Technology Research Center of Water Saving for Crops in Arid Area of Northern Shaanxi, Yulin, China.

出版信息

PLoS One. 2024 Jul 17;19(7):e0305836. doi: 10.1371/journal.pone.0305836. eCollection 2024.

DOI:10.1371/journal.pone.0305836

PMID:39018314

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11253916/

Abstract

In the dryland area of the Loess Plateau in northwest China, long-term excessive fertilization has led to soil compaction and nutrient loss, which in turn limits crop yield and soil productivity. To address this issue, we conducted experiments using environmentally friendly organic fertilizer and bacterium fertilizer. Our goal was to investigate the effects of additional organic and bacterium fertilizer inputs on soil water migration, crop root architecture, and yield formation. We implemented six different fertilizer strategies, namely: Nm (mulching, N 30 kg/ha), NPK1m (mulching, N 60 kg/ha; P 30 kg/ha; K 30 kg/ha), NPK2m (mulching, N 90 kg/ha; P 45 kg/ha; K 30 kg/ha), NPKOm (mulching, N 90 kg/ha; P 45 kg/ha; K 30 kg/ha; organic fertilizer 2 t/ha), NPKBm (mulching, N 60 kg/ha; P 30 kg/ha; K 30 kg/ha; bacterium fertilizer 10 kg/ha), and N (N 30 kg/ha; no mulching). The results revealed that the addition of bacterium fertilizer (NPKBm) had a positive impact on soybean root system development. Compared with the other treatments, it significantly increased the total root length, total root surface area, and total root length density by 25.96% ~ 94.89%, -19.63% ~ 36.28%, and 9.36% ~ 28.84%, respectively. Furthermore, NPKBm enhanced soil water consumption. In 2018, water storage during the flowering and podding periods decreased by 12.63% and 19.65%, respectively, while water consumption increased by 0.97% compared to Nm. In 2019, the flowering and harvest periods decreased by 23.49% and 11.51%, respectively, while water consumption increased by 0.65%. Ultimately, NPKBm achieved high grain yield and significantly increased water use efficiency (WUE), surpassing other treatments by 76.79% ~ 78.97% and 71.22% ~ 73.76%, respectively. Subsequently, NPK1m also exhibited significant increases in yield and WUE, with improvements of 35.58% ~ 39.27% and 35.26% ~ 38.16%, respectively. The use of bacterium fertilizer has a profound impact on soybean root architecture, leading to stable and sustainable grain yield production.

摘要

在中国西北部黄土高原的旱地地区，长期过度施肥导致土壤压实和养分流失，进而限制了作物产量和土壤生产力。为解决这一问题，我们使用环保型有机肥和菌肥进行了试验。我们的目标是研究额外投入有机和菌肥对土壤水分运移、作物根系结构和产量形成的影响。我们实施了六种不同的施肥策略，即：Nm（覆盖，施氮30千克/公顷）、NPK1m（覆盖，施氮60千克/公顷；施磷30千克/公顷；施钾30千克/公顷）、NPK2m（覆盖，施氮90千克/公顷；施磷45千克/公顷；施钾30千克/公顷）、NPKOm（覆盖，施氮90千克/公顷；施磷45千克/公顷；施钾30千克/公顷；有机肥2吨/公顷）、NPKBm（覆盖，施氮60千克/公顷；施磷30千克/公顷；施钾30千克/公顷；菌肥10千克/公顷）和N（施氮30千克/公顷；不覆盖）。结果表明，添加菌肥（NPKBm）对大豆根系发育有积极影响。与其他处理相比，它显著增加了总根长、总根表面积和总根长密度，分别增加了25.96%~~94.89%、-19.63%~~36.28%和9.36%28.84%。此外，NPKBm提高了土壤水分消耗。2018年，开花期和结荚期的储水量分别下降了12.63%和19.65%，而与Nm相比，耗水量增加了0.97%。2019年，开花期和收获期分别下降了23.49%和11.51%，而耗水量增加了0.65%。最终，NPKBm实现了高产，并显著提高了水分利用效率（WUE），分别比其他处理高出76.79%78.97%和71.22%~~73.76%。随后，NPK1m的产量和WUE也显著增加，分别提高了35.58%~~39.27%和35.26%~38.16%。使用菌肥对大豆根系结构有深远影响，从而实现了稳定和可持续的粮食产量生产。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4881/11253916/90868da148a7/pone.0305836.g001.jpg

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额外投入有机肥料和菌肥可调节大豆根系结构和干物质分配，从而在中国半干旱地区实现可持续产量。

Additional organic and bacterium fertilizer input regulated soybean root architecture and dry matter distribution for a sustainable yield in the semi-arid Region of China.

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