Soil splash detachment and its spatial distribution under corn and soybean cover

文献类型: 外文期刊

第一作者: Ma, Bo

作者: Ma, Bo;Liu, Xiaojun;Li, Zhanbin;Ma, Bo;Ma, Fan;Wu, Faqi;Liu, Yuxin;Ma, Fan

作者机构:

关键词: Crop;Splash detachment;Throughfall;Spatial distribution;Rainfall energy

期刊名称:CATENA ( 影响因子:5.198; 五年影响因子:5.594 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: To evaluate the effects of splash erosion on crops, throughfall and splash detachment were measured in different crop-growth stages and rainfall intensities under corn and soybean cover. The relation between splash detachment under the crop canopy and leaf area index and throughfall intensity was analyzed. The characteristics of the spatial distribution of splash detachment under the crop canopy were discussed as well. The results indicated that, compared with bare soil, the average splash detachment rate under the canopy during corn growth was reduced from 77% to 43%, with an average of 68% approximately, while a soybean canopy can reduce the splash detachment rate from 77% to 48% with an average of 61% approximately during the growth stage. The splash erosion detachment rate increased significantly with increasing leaf area index and rainfall intensity. The throughfall was concentrated in the centers of rows as crop grows, and a sharp increase in the splash detachment rate was caused by concentrations of throughfall under the canopy, which resulted in uneven distribution of splash detachment. The spatial distributions of splash detachment depended on the spatial distributions of throughfall under the crop canopy. The change in throughfall intensity under the canopy was the main reason for the variation in splash detachment. The reduction of kinetic energy because of interception by the crop canopy contributed to a decrease in splash erosion. However, large raindrops formed at the tips and edges of leaves can generate substantial erosion, and this part of the splash may become the main portion of splash erosion under the canopy. These results indicated that continuous and concentrated raindrops impacted splash detachment and caused its uneven distribution under crop cover. (C) 2014 Elsevier B.V. All rights reserved.

分类号: S15

  • 相关文献

[1]Degradation of four fungicides in tropical soils from Hainan, China. Han, Bing Jun,Peng, Li Xu,Chen, Li Xia.

[2]Response of soil moisture under different crop planting to precipitation in Central Hill Region, Sichuan Basin. Liang, Chuan,Long, Xunjian,Zhang, Chunmin,Zhang, Chunmin. 2011

[3]Interpreting RADARSAT-2 Quad-Polarization SAR Signatures From Rice Paddy Based on Experiments. Yang, Shenbin,Zhao, Xiaoyan,Hua, Guoqiang,Li, Bingbai. 2012

[4]CROP DISCRIMINATION IN SHANDONG PROVINCE BASED ON PHENOLOGY ANALYSIS OF MULTI-YEAR TIME SERIES. Xu, Qingyun,Yang, Guijun,Long, Huiling,Xu, Qingyun,Wang, Chongchang,Xu, Qingyun,Wang, Chongchang,Xu, Qingyun,Yang, Guijun,Long, Huiling. 2013

[5]A SVM-Based Text Classification System for Knowledge Organization Method of Crop Cultivation. Ji, Laiqing,Cheng, Xinrong,Kang, Li,Li, Daoliang,Li, Daiyi,Chen, Yingyi,Wang, Kaiyi. 2012

[6]Multi-Scale Reconstruction of Crop Canopy. Lu, Shenglian,Guo, Xinyu,Zhao, Chunjiang,Qian, Tingting,Wen, Weiliang,Du, Jianjun. 2012

[7]Developing a photosynthetic sterility model to estimate CO2 fixation through the crop yield in Asia with the aid of MODIS data. Kaneko, Daijiro,Yeh, P. J. -F.,Kumakura, Toshiro,Yang, Peng. 2010

[8]Manipulation of Metabolic Pathways to Develop Vitamin-Enriched Crops for Human Health. Jiang, Ling,Wang, Weixuan,Lian, Tong,Zhang, Chunyi,Jiang, Ling,Wang, Weixuan,Zhang, Chunyi. 2017

[9]EXTRACTING SPATIAL INFORMATION OF HARVEST INDEX FOR WINTER WHEAT BASED ON MODIS NDVI IN NORTH CHINA. Ren, Jianqiang,Chen, Zhongxin,Tang, Huajun,Ren, Jianqiang,Chen, Zhongxin,Tang, Huajun,Liu, Xingren. 2010

[10]Trends in grain yields and soil organic C in a long-term fertilization experiment in the China Loess Plateau. Xu, Minggang,Fan, Tinglu,Song, Shangyou,Fan, Tinglu,Zhou, Guangye,Ding, Linping.

[11]Estimation of crop LAI using hyperspectral vegetation indices and a hybrid inversion method. Liang, Liang,Zhang, Lianpeng,Lin, Hui,Liang, Liang,Zhao, Shuhe,Liang, Liang,Di, Liping,Deng, Meixia,Qin, Zhihao.

[12]Use of allelopathy for weed management in China - A Review. Zhang, CX.

[13]Chromosome elimination, addition and introgression in intertribal partial hybrids between Brassica rapa and Isatis indigotica. Tu, Yuqin,Sun, Jian,Ge, Xianhong,Li, Zaiyun,Sun, Jian.

[14]Catastrophic Risk Assessment of Crops Caused by Flood Based on Vulnerability-Using Northeast China as a Case. Zhao, Sijian,Zhang, Qiao. 2014

[15]The miR156/SPL Module, a Regulatory Hub and Versatile Toolbox, Gears up Crops for Enhanced Agronomic Traits. Wang, Hai,Wang, Haiyang. 2015

[16]EFFECTS OF DIGESTATE FROM SWINE MANURE DIGESTER ON IN VITRO GROWTH OF CROP FUNGAL PATHOGENS: A LABORATORY STUDY. Tao, X.,Shang, B.,Dong, H.,Chen, Y.,Xin, H..

[17]Soil losses due to potato and sugar beet harvesting in NE China. Li, Y.,Ruysschaert, G.,Poesen, J.,Zhang, Q. W.,Bai, L. Y.,Li, L.,Sun, L. F..

[18]Spectrum analysis of crop and weeds at seedling. Mao, WH,Wang, YQ,Wang, YM,Zhang, XC. 2005

[19]Climate changes and trends in phenology and yields of field crops in China, 1981-2000. Tao, Fulu,Yokozawa, Masayuki,Xu, Yinlong,Hayashi, Yousay,Zhang, Zhao. 2006

[20]A Study on Recognition and Assessment of Agricultural Weather-related Disaster Risk. Zhao, Sijian. 2016

作者其他论文 更多>>

微信小程序