[1]卢爱刚,索安宁,张镭.基于SWAT模型的黄土高原典型区水土流失格局模拟评价[J].水土保持研究,2011,18(02):57-61,65.
 LU Ai-gang,SUO An-ning,ZHANG Lei.Simulation of Spatial Pattern of Soil Water Loss in a Watershed of the Loess Plateau Based SWAT Model[J].Research of Soil and Water Conservation,2011,18(02):57-61,65.
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基于SWAT模型的黄土高原典型区水土流失格局模拟评价

《水土保持研究》[ISSN:1005-3409/CN:61-1272/P] 卷: 18 期数: 2011年02期 页码: 57-61,65 栏目: 出版日期: 2011-04-20
Title:
Simulation of Spatial Pattern of Soil Water Loss in a Watershed of the Loess Plateau Based SWAT Model
作者:
卢爱刚1, 索安宁2, 张镭3
1. 渭南师范学院, 陕西 渭南 714000;
2. 国家海洋环境监测中心, 辽宁 大连 116023;
3. 陕西省科学器材公司, 西安 710054
Author(s):
LU Ai-gang1, SUO An-ning2, ZHANG Lei3
1. Department of Environment and Life Sciences, Weinan Teachers University, Weinan, Shaanxi 714000, China;
2. National Marine Environment Monitor Center, Dalian, Liaoning 116023, China;
3. Scientific Equipment Company of Shaanxi Province, Xi’an 710054, China
关键词:
水土流失空间格局SWAT模型土地覆被汭河流域
Keywords:
soil water lossspatial patternSWAT modelland coverRuihe watershed
分类号:
S157.1
摘要:
运用分布式生态水文模型SWAT对黄土高原典型区汭河流域的本底径流深度、本底侵蚀模数、现状径流深度、现状侵蚀模数分别进行了模拟研究,并以本底径流深度和本底侵蚀深度为标准分别对流域的现状径流和现状侵蚀进行定量空间评价。研究结果表明:(1)SWAT模型能够准确地模拟汭河流域水土流失总量及其空间格局。(2)汭河流域上游的多数集水区本底径流深度为70 mm,占流域面积的68.68%,流域中下游集水区本底径流深度多数为60 mm,占流域面积的28.96%。流域土壤侵蚀模数普遍在8 t/hm2以下,只有极少数集水区的侵蚀模数在8~20 t/hm2之间。(3)随着土地覆被盖度的增高,流域径流量减小,输沙量也减小,蒸发量增加,径流深度和侵蚀模数的空间异质性变小,水土流失的风险降低。(4)土壤侵蚀模数的空间异质性比径流深度的空间异质性对土地覆被变化更为敏感,5种土地覆被情景中,土壤侵蚀模数的空间异质性的大小顺序是:耕地、低覆盖度草地>裸地、沙化土地>当前土地覆被>疏林、草地>林地。
Abstract:
The spatial patterns of soil water loss were simulated in five different landscapes in Ruihe watershed on the Loess Plateau using distributed hydrological model SWAT. And results showed: (1) SWAT model can reasonably describe the soil water loss and its spatial pattern; (2) The background depth of the streams in most catchments of the upstream of Nahe River is 70 mm, accounting for 68.68% of the total catchments; and the depth of the streams of the downriver catchments is 60 mm, accounting for 68.68% of the total catchments, and most of the erosion modulus of the soil of the whole catchments is less than 8 t/hm2, with only a few between 8~20 t/hm2; (3) Both the runoff and sediment transport decreased with increase of land cover, companying by decrease of spatial heterogeneity and security of soil water loss;(4) The spatial heterogeneity of erosion modulus is more sensitive to land cover change than that of depth of runoff, and the order of the spatial heterogeneity of erosion modulus in 5 landscape types is farm-low density and ranks as grass landscape>bare-desert landscape>current landscape>forest-grass landscape>forest landscape.

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备注/Memo

收稿日期:2010-5-7;改回日期:2010-9-21。
基金项目:陕西省科技厅面上项目(2010JM5014);陕西省教育厅科研项目(09JK429);渭南市科技局重大科技专项(2010GC1-6)
作者简介:卢爱刚(1968- ),男,陕西富平人,博士,教授,主要从事全球变化区域响应研究。E-mail:lagx1088@163.com

更新日期/Last Update: 1900-01-01