Winter legumes in rice crop rotations reduces nitrogen loss, and improves rice yield and soil nitrogen supply

文献类型: 外文期刊

第一作者: Yu, Yingliang

作者: Yu, Yingliang;Xue, Lihong;Yang, Linzhang

作者机构:

关键词: Rice yield;Soil nitrogen supply capacity;Non-point pollution;Crop rotations;Legumes;Chemical nitrogen fertilizer reduction;Runoff nitrogen loss

期刊名称:AGRONOMY FOR SUSTAINABLE DEVELOPMENT ( 影响因子:5.832; 五年影响因子:9.354 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: Intensive irrigated rice-wheat crop systems have caused serious soil depletion and nitrogen loss in the Tai Lake region of China. A possible solution is the incorporation of legumes in rice because legumes are a source of nitrogen. There is actually little knowledge on the impact of legumes on rotation, soil fertility, and nitrogen loss. Therefore, we studied the effect of five rice-based rotations, including rice-wheat, rice-rape, rice-fallow, rice-bean, and rice-vetch, on soil nitrogen, rice yield,and runoff loss. A field experiment was conducted in the Tai Lake region from 2009 to 2012. Crop residues from rape, bean, and vetch were used to partially replace chemical fertilizer in rice. Results show that replacing 9.5-21.4 % of mineral nitrogen fertilizer by residues maintained rice yields of rice-rape, rice-bean, and rice-vetch rotations, compared to the rice-wheat reference. Moreover, using legumes as a winter crop in rice-bean and rice-vetch combinations increased rice grain yield over 5 %, and increased rice residue nitrogen content by 9.7-20.5 %. Nitrogen runoff decreased 30-60 % in rice-rape, rice-bean, and rice-vetch compared with rice-wheat. Soil mineral nitrogen and microbial biomass nitrogen content were also improved by application of leguminous residues.

分类号: S

  • 相关文献

[1]Chronosequence of paddy soils and phosphorus sorption-desorption properties. Zou, Ping,Fu, Jianrong,Cao, Zhihong. 2011

[2]Soil Microbiological and Biochemical Properties as Affected by Different Long-Term Banana-Based Rotations in the Tropics. Zhong Shuang,Jin Zhiqiang,Zhong Shuang,Zeng Huicai. 2015

[3]Effect of tillage and rotation on organic carbon forms of chernozemic soils in Saskatchewan. Wu, TY,Schoenau, JJ,Li, FM,Qian, PY,Malhi, SS,Shi, YC.

[4]Molecular phylogeny and dynamic evolution of disease resistance genes in the legume family. Zheng, Fengya,Wong, Fuk-Ling,Zhao, Shancen,Lam, Hon-Ming,Zheng, Fengya,Wong, Fuk-Ling,Zhao, Shancen,Lam, Hon-Ming,Wu, Haiyang,Li, Shiming,He, Weiming,Zhao, Shancen,Wu, Haiyang,Wu, Haiyang,Zhang, Rongzhi,Li, Genying. 2016

[5]Nitrogen uptake and transfer in broad bean and garlic strip intercropping systems. Tang Qiu-xiang,Jiang Ping-an,Tang Qiu-xiang,Liu Hong-bin,Zhai Li-mei,Haile Tewolde,Ren Tian-zhi,Lei Bao-kun,Lin Tao,Liu En-ke. 2018

[6]Legume Crops Phylogeny and Genetic Diversity for Science and Breeding. Smykal, Petr,Coyne, Clarice J.,Hu, Jinguo,Ambrose, Mike J.,Maxted, Nigel,Schaefer, Hanno,Blair, Matthew W.,Berger, Jens,Greene, Stephanie L.,Nelson, Matthew N.,Besharat, Naghmeh,Varshney, Rajeev K.,Nelson, Matthew N.,Besharat, Naghmeh,Varshney, Rajeev K.,Vymyslicky, Tomas,Toker, Cengiz,Saxena, Rachit K.,Roorkiwal, Manish,Pandey, Manish K.,Varshney, Rajeev K.,Li, Ying H.,Wang, Li X.,Guo, Yong,Qiu, Li J.,Redden, Robert J..

[7]Biological Potential of Sixteen Legumes in China. Yao, Yang,Cheng, Xuzhen,Wang, Lixia,Wang, Suhua,Ren, Guixing. 2011

[8]Crop acquisition of phosphorus, iron and zinc from soil in cereal/legume intercropping systems: a critical review. Xue, Yanfang,Xia, Haiyong,Xia, Haiyong,Zhang, Zheng,Christie, Peter,Li, Long,Tang, Caixian.

[9]Satellite Remote Sensing Experiment That Evaluates Rotational Effect of Rice in Bean-Rice Rotation. Sun, Ling,Zhu, Zesheng. 2016

[10]Rice yield, potassium uptake and apparent balance under long-term fertilization in rice-based cropping systems in southern China. Zhang, Huimin,Xu, Minggang,Shi, Xiaojun,Li, Zuzhang,Huang, Qinghai,Wang, Xiujun.

[11]Geographical Variation of Climate Change Impact on Rice Yield in the Rice-Cropping Areas of Northeast China during 1980-2008. Liu, Zhenhuan,Zhang, Guojie,Yang, Peng. 2016

[12]Impact of temperature changes on early-rice productivity in a subtropical environment of China. Huang, Min,Jiang, Ligeng,Zhang, Weixing,Zou, Yingbin,Zou, Yingbin. 2013

[13]Influence of the Improved System of Rice Intensification (SRI) on Rice Yield, Yield Components and Tillering Characteristics under Different Rice Establishment Methods. Chen, Song,Wang, Dangying,Xu, Chunmei,Zhang, Xiufu,Zheng, Xi.

[14]A simple assessment on spatial variability of rice yield and selected soil chemical properties of paddy fields in South China. Liu, Zhanjun,Zhou, Wei,He, Ping,Lei, Qiuliang,Liang, Guoqing,Liu, Zhanjun,Shen, Jianbo.

[15]Population structure and association analysis of yield and grain quality traits in hybrid rice primal parental lines. Wang, Yingheng,Xie, Huaan,Wang, Yingheng,Zheng, Yanmei,Cai, Qiuhua,Mao, Xiaohui,Xie, Hongguang,Zhu, Yongsheng,Lian, Lin,Luo, Xi,Xie, Huaan,Zhang, Jianfu,Wang, Yingheng,Zheng, Yanmei,Cai, Qiuhua,Mao, Xiaohui,Xie, Hongguang,Zhu, Yongsheng,Lian, Lin,Luo, Xi,Xie, Huaan,Zhang, Jianfu,Wang, Yingheng,Zheng, Yanmei,Cai, Qiuhua,Liao, Changjian,Mao, Xiaohui,Xie, Hongguang,Zhu, Yongsheng,Lian, Lin,Luo, Xi,Xie, Huaan,Zhang, Jianfu,Wang, Yingheng,Zheng, Yanmei,Cai, Qiuhua,Liao, Changjian,Mao, Xiaohui,Xie, Hongguang,Zhu, Yongsheng,Lian, Lin,Luo, Xi,Xie, Huaan,Zhang, Jianfu,Wang, Yingheng,Zheng, Yanmei,Cai, Qiuhua,Mao, Xiaohui,Xie, Hongguang,Zhu, Yongsheng,Lian, Lin,Luo, Xi,Xie, Huaan,Zhang, Jianfu.

[16]Effects of common Echinochloa varieties on grain yield and grain quality of rice. Gu, Tao,Yang, Xia,Li, Yongfeng,Zhao, Buhong,Peng, Qiong,Bai, Lianyang.

[17]Thiamethoxam seed treatment for control of rice thrips (Chloethrips oryzae) and its effects on the growth and yield of rice (Oryza sativa). Liu, Xueyuan,Wang, Pei,Fu, Wei,Ma, Mingyong.

作者其他论文 更多>>

微信小程序