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再生稻适当减氮增磷提高了中国东南部地区的产量并减少了温室气体排放。

Appropriately Reduced Nitrogen and Increased Phosphorus in Ratooning Rice Increased the Yield and Reduced the Greenhouse Gas Emissions in Southeast China.

作者信息

Yang Yuncheng, Yao Feifei, Sun Yangbo, Yang Zhipeng, Li Rong, Bai Ge, Lin Wenxiong, Chen Hongfei

机构信息

College of JunCao Sciences and Ecology, Fujian Agriculture and Forestry University, Fuzhou 350002, China.

Fujian Provincial Key Laboratory of Agroecological Processing and Safety Monitoring, Fujian Agriculture and Forestry University, Fuzhou 350002, China.

出版信息

Plants (Basel). 2024 Feb 2;13(3):438. doi: 10.3390/plants13030438.

DOI:10.3390/plants13030438
PMID:38337971
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10857620/
Abstract

Reducing greenhouse gas emissions while improving productivity is the core of sustainable agriculture development. In recent years, rice ratooning has developed rapidly in China and other Asian countries, becoming an effective measure to increase rice production and reduce greenhouse gas emissions in these regions. However, the lower yield of ratooning rice caused by the application of a single nitrogen fertilizer in the ratooning season has become one of the main reasons limiting the further development of rice ratooning. The combined application of nitrogen and phosphorus plays a crucial role in increasing crop yield and reducing greenhouse gas emissions. The effects of combined nitrogen and phosphorus application on ratooning rice remain unclear. Therefore, this paper aimed to investigate the effect of combined nitrogen and phosphorus application on ratooning rice. Two hybrid rice varieties, 'Luyou 1831' and 'Yongyou 1540', were used as experimental materials. A control treatment of nitrogen-only fertilization (187.50 kg·ha N) was set, and six treatments were established by reducing nitrogen fertilizer by 10% (N1) and 20% (N2), and applying three levels of phosphorus fertilizer: N1P1 (168.75 kg·ha N; 13.50 kg·ha P), N1P2 (168.75 kg·ha N; 27.00 kg·ha P), N1P3 (168.75 kg·ha N; 40.50 kg·ha P), N2P1 (150.00 kg·ha N; 13.50 kg·ha P), N2P2 (150.00 kg·ha N; 27.00 kg·ha P), and N2P3 (150.00 kg·ha N; 40.50 kg·ha P). The effects of reduced nitrogen and increased phosphorus treatments in ratooning rice on the yield, the greenhouse gas emissions, and the community structure of rhizosphere soil microbes were examined. The results showed that the yield of ratooning rice in different treatments followed the sequence N1P2 > N1P1 > N1P3 > N2P3 > N2P2 > N2P1 > N. Specifically, under the N1P2 treatment, the average two-year yields of 'Luyou 1831' and 'Yongyou 1540' reached 8520.55 kg·ha and 9184.90 kg·ha, respectively, representing increases of 74.30% and 25.79% compared to the N treatment. Different nitrogen and phosphorus application combinations also reduced methane emissions during the ratooning season. Appropriately combined nitrogen and phosphorus application reduced the relative contribution of stochastic processes in microbial community assembly, broadened the niche breadth of microbial communities, enhanced the abundance of functional genes related to methane-oxidizing bacteria and soil ammonia-oxidizing bacteria in the rhizosphere, and decreased the abundance of functional genes related to methanogenic and denitrifying bacteria, thereby reducing greenhouse gas emissions in the ratooning season. The carbon footprint of ratooning rice for 'Luyou 1831' and 'Yongyou 1540' decreased by 25.82% and 38.99%, respectively, under the N1P2 treatment compared to the N treatment. This study offered a new fertilization pattern for the green sustainable development of rice ratooning.

摘要

在提高生产力的同时减少温室气体排放是可持续农业发展的核心。近年来,再生稻在中国和其他亚洲国家发展迅速,成为这些地区增加水稻产量和减少温室气体排放的有效措施。然而,再生季单施氮肥导致再生稻产量较低,已成为限制再生稻进一步发展的主要原因之一。氮磷配施在提高作物产量和减少温室气体排放方面起着至关重要的作用。氮磷配施对再生稻的影响尚不清楚。因此,本文旨在研究氮磷配施对再生稻的影响。选用两个杂交水稻品种‘绿优1831’和‘甬优1540’作为试验材料。设置纯氮施肥(187.50 kg·ha N)的对照处理,并通过减少10%(N1)和20%(N2)的氮肥用量,设置六个处理,并施用三个水平的磷肥:N1P1(168.75 kg·ha N;13.50 kg·ha P)、N1P2(168.75 kg·ha N;27.00 kg·ha P)、N1P3(168.75 kg·ha N;40.50 kg·ha P)、N2P1(150.00 kg·ha N;13.50 kg·ha P)、N2P2(150.00 kg·ha N;27.00 kg·ha P)和N2P3(150.00 kg·ha N;40.50 kg·ha P)。研究了再生稻减氮增磷处理对产量、温室气体排放和根际土壤微生物群落结构的影响。结果表明,不同处理下再生稻产量顺序为N1P2>N1P1>N1P3>N2P3>N2P2>N2P1>N。具体而言,在N1P2处理下,‘绿优1831’和‘甬优1540’的两年平均产量分别达到8520.55 kg·ha和9184.90 kg·ha,与N处理相比分别增加了74.30%和25.79%。不同的氮磷施用组合也降低了再生季的甲烷排放。适当的氮磷配施降低了微生物群落组装中随机过程的相对贡献,拓宽了微生物群落的生态位宽度,提高了根际与甲烷氧化细菌和土壤氨氧化细菌相关功能基因的丰度,降低了与产甲烷和反硝化细菌相关功能基因的丰度,从而减少了再生季的温室气体排放。与N处理相比,在N1P2处理下,‘绿优1831’和‘甬优1540’再生稻的碳足迹分别下降了25.82%和38.99%。本研究为再生稻绿色可持续发展提供了一种新的施肥模式。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/332a/10857620/263f09601373/plants-13-00438-g008.jpg
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