Long‐term fertilization regulates dissimilatory nitrate reduction processes by altering paddy soil organic carbon components

Li, Chenglin; Wei, Zhijun; Wang, Xiaomin; Ma, Xiaofang; Yang, Pinpin; Shan, Jun; Yan, Xiaoyuan

doi:10.1111/sum.12994

Soil Use and Management

2023

DOI: 10.1111/sum.12994

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Long‐term fertilization regulates dissimilatory nitrate reduction processes by altering paddy soil organic carbon components

Chenglin Li,

Zhijun Wei,

Xiaomin Wang

et al.

Abstract: To enhance rice yields, synthetic nitrogen (N) fertilizers are often applied in rice paddy fields. Under waterlogged conditions, denitrification, anaerobic ammonium oxidation (anammox) and dissimilatory nitrate reduction to ammonium (DNRA) are the main N transformation processes. However, the effects of long‐term fertilization on the dissimilatory nitrate reduction processes remain largely unclear. Here, we investigated rates of denitrification, anammox and DNRA and the abundance of bacterial and nitrate reduc… Show more

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2024

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Cited by 2 publications

References 103 publications

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Effects of warming and fertilization on nirK-, nirS- and nosZ-type denitrifier communities in paddy soil

Deng,

Xu,

Zhang

et al. 2024

Science of The Total Environment

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Effects of warming and fertilization on nirK-, nirS- and nosZ-type denitrifier communities in paddy soil

Deng,

Xu,

Zhang

et al. 2024

Science of The Total Environment

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Effect of Glycolipids Application Combined with Nitrogen Fertilizer Reduction on Maize Nitrogen Use Efficiency and Yield

Meng,

Dong,

Wang

et al. 2024

Plants

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Microbial-driven N turnover is important in regulating N fertilizer use efficiency through the secretion of metabolites like glycolipids. Currently, our understanding of the potential of glycolipids to partially reduce N fertilizer use and the effects of glycolipids on crop yield and N use efficiency is still limited. Here, a three-year in situ field experiment was conducted with seven treatments: no fertilization (CK); chemical N, phosphorus and potassium (NPK); NPK plus glycolipids (N+PKT); and PK plus glycolipids with 10% (0.9 N+PKT), 20% (0.8 N+PKT), 30% (0.7 N+PKT), and 100% (PKT) N reduction. Compared with NPK, glycolipids with 0–20% N reduction did not significantly reduce maize yields, and also increased N uptake by 6.26–11.07%, but no significant changes in grain or straw N uptake. The N resorption efficiency under 0.9 N+PKT was significantly greater than that under NPK, while the apparent utilization rates of N fertilizer and partial factor productivity of N under 0.9 N+PKT were significantly greater than those under NPK. Although 0.9 N+PKT led to additional labor and input costs, compared with NPK, it had a greater net economic benefit. Our study demonstrates the potential for using glycolipids in agroecosystem management and provides theoretical support for optimizing fertilization strategies.

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Long‐term fertilization regulates dissimilatory nitrate reduction processes by altering paddy soil organic carbon components

Cited by 2 publications

References 103 publications

Effects of warming and fertilization on nirK-, nirS- and nosZ-type denitrifier communities in paddy soil

Effects of warming and fertilization on nirK-, nirS- and nosZ-type denitrifier communities in paddy soil

Effect of Glycolipids Application Combined with Nitrogen Fertilizer Reduction on Maize Nitrogen Use Efficiency and Yield

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