Reducing environmental risk by improving crop management practices at high crop yield levels

•Newly bred ‘super’ varieties can achieve their yield potential at very high N rates.•Optimized crop management practices improve both grain yield and N use efficiency.•Improved soil fertility and root activities contribute greatly to the N uptake of rice.•Crop managements reduce environmental risk...

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Bibliographic Details
Published in:Field crops research 2021-05, Vol.265, p.108123, Article 108123
Main Authors: Chen, Liang, Xie, Hao, Wang, Guiliang, Yuan, limin, Qian, Xiaoqin, Wang, Weilu, Xu, Yunji, Zhang, Weiyang, Zhang, Hao, Liu, Lijun, Wang, Zhiqin, Gu, Junfei, Yang, Jianchang
Format: Article
Language:English
Subjects:
Crop management
Environmental risk
Grain yield
N use efficiency
Rice
Soil texture
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Summary:•Newly bred ‘super’ varieties can achieve their yield potential at very high N rates.•Optimized crop management practices improve both grain yield and N use efficiency.•Improved soil fertility and root activities contribute greatly to the N uptake of rice.•Crop managements reduce environmental risk by decreasing N residues in the soil. ‘High input, high output’ intensive agriculture in China has contributed greatly to food security, but caused heavy agricultural nitrogen (N) losses. Modern Agriculture faces the dual challenges of increasing food supply and protecting the environment for sustainable agriculture. In order to reduce N losses in rice production systems, two field experiments at different N levels (Exp. I) and integrated crop management practices (Exp. II) were conducted. The results indicated that the newly bred ‘super’ rice varieties have great yield potentials, but this can only be realized at very high N rates with low N efficiency, and large amounts of N residue in the soil. However, by adopting multiple crop management practices, including increasing the crop density, optimizing the amount and ratio of N applications, using an alternate wetting and soil drying irrigation pattern, adding organic fertilizer, and increasing tillage depth, soil structure, soil enzymatic activities, and root activities were significantly improved. The improved soil fertility and root activities contributed greatly to the nutrient uptake ability of crops, and decreased N residues in the soil. With multiple crop management practices, the N fertilizer input was reduced by 10 %, the fertilizer N recovery efficiency was increased by 40.7 %, and N losses to the environment were decreased by 47.8 %, compared with local farmers’ practices. Considering the urgency of reducing the adverse environmental risks of N losses and pollution from rice production without sacrificing rice yield, multiple crop management practices should be adopted in rice production, especially at high crop yield levels with large N inputs.
ISSN:0378-4290
1872-6852
DOI:10.1016/j.fcr.2021.108123