[1] Wischmeier W H, Smith D D.A universal soil loss equation to guide conservation farm planning.Trans.7th International Cong[J].Soil Sci, 1960, I:418-425.
[2] Wischmeier W H.Use and misused of the universal soil loss equation[J].J Soil and Water Cons, 1976, 31(1):5-9.
[3] Meyer L D.Evolution of the Universal Soil Loss Equation[J].J.Soil and Water Cons, 1984, 32(2):99-104.
[4] Renard K D, Forste G D, Weesies G A.Prediction rainfall erosion by water:a guild to conservation planning with the revised universal soil loss equation (RUSLE)[S].USDA Agricultural Handbook No.703, 1997.
[5] Nearing M A, Foster G R, Lane L J, et al.A process-based soil erosion model for USDA-Water Erosion Prediction Project Technology[J].Trans.ASAE, 1989.32:1587-1593.
[6] USDA-Water Erosion Prediction Project.NSERL No.2.National Soil Erosion Research Laboratory[R].USDA-ARS.West Lafayette.
[7] Flanagan D C.WEPP CD-ROM[M/CD].2001 Vision.
[8] Dept.of Physical Geography, Univ.of Utrecht.LISEM.A User Mannual[S].1995.
[9] De Roo A P J, Wesseling C G, Ritsema C J.LISEM:A single-event physically based hydrological and soil erosion model for drainage basins.Ⅱ:sensitivity analysis, validation and application[J].Hydrological Processes, 1996, 10:1107-1118.
[10] Morgan R P C, Quinton J N, Smith R E, et al.The European Soil Erosion Model (EUROSEM):documentation and user guide[S].Silsoe College, Cranfield University, 1998.
[11] Morgan R P C, Quinton J N, Smith R E, et al.The European Soil Erosion Model (EUROSEM):A dynamic approach for predicting sediment transport from fields and small catchments[J].Earth Surface Processes and Landforms, 1998, 23(6):527-544.
[12] Govers G.Empirical relationships for the transport capacity of overland flow[M].IAHS publication, 1990.No.189.45-63.
[13] Everaert W.Empirical relations for the sediment transport capacity of interrill flow[J].Earth Surface Processes and Landforms, 1991, 16:513-532.
[14] De Roo A P J, Jetten V G.Calibrating and validating the LISEM Model for two data sets from the Netherlands and South Africa[J].Catena, 1999, 37(3-4):477-493.
[15] De Roo A P J, Wesseling C G, Ritsema C J.LISEM:A single-event physically based hydrological and soil erosion model for drainage basins.I:Theory, Input and Output[J].Hydrological Processes, 1996, 10(8):1107-1118.
[16] 杨勤科, 李锐.LISEM:一个基于GIS的流域土壤流失预报模型[J].水土保持通报, 1998, 18(3):82-89.
[17] De Jong S M, Paracchini M L, Bertolo F, et al.Regional assessment of soil erosion using the distributed model SEMMED and remotely sensed data[J].Catena, 1999, 37(3-4):291-308.
[18] Favis-Mortlock D T.A self-organising dynamic systems approach to the simulation of rill initiation and development on hillslopes[J].Computers and Geosciences, 1998, 24(4):353-372.
[19] Favis-Mortlock D T, Boardman J, Parsons A J, et al.Emergence and erosion:a model for rill initiation and development[J].Hydrological Processes, 2000, 14(6):2173-2205.
[20] Groundwater, P.The influence of model resolution on rill development:A numerical modelling study[J].Hydrological Processes, 2000, 14(6):2173-2205.
[21] Woodward D E.Method to predict cropland ephemeral gully erosion[J].Catena, 1999, 37(2):393-399.
[22] Nachtergaele J, Poesen J, Vandekerckhove L, et al.Testing the Ephemeral Gully Erosion Model (EGEM) for two Mediterranean environments[J].Earth Surface Processes and Landforms, 2001, 26(1):17-30.
[23] Sidorchuk Aleksey, Sidorchuk Anna.Model for estimating gully morphology[M].IAHS publication, No.249, 1998.333-343.
[24] Sidorchuk A.Dynamic and static models of gully erosion[J].Catena, 1999, 37(3-4):401-414.
[25] Woolhiser D A, Smith R E, Goodrich D C.KINEROS, A kinematic runoff and erosion model:documentation and user manual[S].USDA-Agricultural Research Service, 1990, ARS-77:130.
[26] Morgan R P C, Morgan D D V, Finney H J.A predictive model for the assessment of soil erosion Risk[J].Agricultural Engineering Research, 1984, 30:245-253.
[27] Favis-Mortlock D, Guerra T, Boardman J.A self-organizing systems approach to hillslop rill initiation and growth:model development and validation[M].IAHS publication, No.249, 1998.53-61.
[28] 江忠善, 王志强, 刘志.黄土丘陵区小流域土壤侵蚀空间变化定量研究[J].土壤侵蚀与水土保持学报, 1996, 2(1):1-9.
[29] 江忠善, 王志强, 刘志.应用地理信息系统评价黄土丘陵区小流域土壤侵蚀的研究[A].见:第二届全国泥沙基本理论研究学术讨论会论文集[C].北京:中国建材工业出版社, 1995.207-275.
[30] 蔡强国, 陆兆熊, 王贵平.黄土丘陵沟壑区典型小流域侵蚀产沙过程模拟[J].地理学报, 1996, 51(2):108-116.
[31] 蔡强国, 王贵平, 陈永宗.黄土高原小流域侵蚀产沙过程与模拟[M].北京:科学出版社, 1998.
[32] 吴礼福.黄土高原土壤侵蚀模型及其应用[J].水土保持通报, 1996, 16(5):29-35.
[33] 张宪奎, 许靖华, 邓育江, 等.黑龙江省土壤侵蚀方程的研究[J].水土保持通报, 1992, 12(4):1-9.
[34] 林素兰, 黄毅, 聂振刚, 等.辽北低山丘陵区坡耕地土壤流失方程的建立[J].土壤通报, 1997, 28(6):261-253.
[35] 杨武德, 陈宝林, 徐锴.红壤坡地不同利用方式土壤侵蚀模型研究[J].土壤侵蚀与水土保持学报, 1999, 5(1):52-58.
[36] 杨子生.滇东北山区坡耕地土壤流失方程研究[J].水土保持通报, 1999, 19(1):1-9.
[37] 黄炎和, 卢程隆, 付勤, 等.闽东南土壤流失预报研究[J].水土保持学报, 1993, 7(4):13-18.
[38] 周伏建, 陈明华, 林福兴, 等.福建省土壤流失预报研究[J].水土保持通报, 1995, 9(1):25-30.
[39] 金争平, 赵焕勋, 和泰, 等.皇甫川小流域土壤侵蚀量预报模型方程研究[J].水土保持学报, 1991, 5(1):8-18.
[40] 金争平, 高志明, 王正文, 等.皇甫川流域小流域地块土壤侵蚀预报模型及其应用[A].见:黄河皇甫川流域土壤侵蚀系统模型和治理模式[C].北京:海洋出版社, 1992.60-84.
[41] 杨艳生, 史德明, 吕喜玺.长江三峡区的坡面土壤流失量和入江泥沙量研究[J].水土保持学报, 1991, 5(3):22-27.
[42] 陈法扬, 王志明.通用土壤流失方程在小良水土保持试验站的应用[J].水土保持通报, 1992, 12(1):23-41.
[43] 江忠善, 宋文径.黄河中游黄土丘陵沟壑区小流域产沙量计算[A].见:第一次河流泥沙国际学术讨论会论文集[C].北京:光华出版社, 1980.A3-1-A3-10.
[44] 牟金泽, 熊贵枢.陕北小流域产沙量预报及水土保持措施拦沙计算[A].见:第一次河流泥沙国际学术讨论会文集[A].北京:光华出版社, 1980.A4-1-A4-10.
[45] 尹国康, 陈钦峦.黄土高原小流域特性指标与产沙统计模式[J].地理学报, 1989, 44(1):32-45.
[46] 范瑞瑜.黄河中游地区小流域土壤流失量计算方程的研究[J].中国水土保持, 1985, (2):12-18.
[47] 王星宇.黄土地区流域产沙数学模型[J].泥沙研究, 1987, (3):55-60.
[48] 汤立群, 陈国祥, 蔡名扬.黄土丘陵区小流域产沙数学模型[J].河海大学学报, 1990, 18(6):10-16.
[49] 谢树楠, 王孟楼, 张仁.黄河中游黄土沟壑区暴雨产沙模型的研究[M].北京:清华大学出版社, 1990.
[50] 周佩华, 李银锄, 黄义端, 等.2000年中国水土流失趋势预测及其防治对策[J].中国科学院西北水土保持研究所集刊, 1988, 第7集:57-71.
[51] 胡良军, 李锐, 杨勤科, 等.基于GIS的区域水土流失评价模型[J].应用基础与工程科学学报, 2000, 8(1):1-8.
[52] 胡良军, 李锐, 杨勤科.基于GIS的区域水土流失评价研究[J].土壤学报, 2001, 38(2):169-174.
[53] 周佩华, 柴宗新, 刘万铨, 等.黄土高原与长江上游地区水土流失变化趋势预测[A].见:丁一汇.中国西部环境演变评估[M].北京:科学出版社, 2002.114-139.
[54] 李矩章, 景可, 李凤新.黄土高原多沙区侵蚀模型探讨[J].地理科学进展, 1999, 18(1):46-53.
[55] 景可, 李矩章, 李风新, 等.黄河中游侵蚀量及趋势预测[J].地理学报, 1998, 53(增刊):107-115.
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WANG Hong-zhi.Development of Eco-environment Construction of Urban Soil and Water Conservation in Leshan City[J].Research of Soil and Water Conservation,2000,7(04):32.
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LU Jin-wei,LI Zhan-bin.Advance in Soil Aggregate Study[J].Research of Soil and Water Conservation,2002,9(04):81.
[3]戴长雷,迟宝明.地下水监测研究进展[J].水土保持研究,2005,12(02):86.
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[4]张心昱,陈利顶.土壤质量评价指标体系与评价方法研究进展与展望[J].水土保持研究,2006,13(03):30.
ZHANG Xin-yu,CHEN Li-ding.The Progress and Prospect of Soil Quality Indicators and Evaluation Methods[J].Research of Soil and Water Conservation,2006,13(04):30.
[5]庞靖鹏,徐宗学,刘昌明.SWAT模型研究应用进展[J].水土保持研究,2007,14(03):31.
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收稿日期:2004-7-10;改回日期:。
基金项目:中国科学院知识创新重要方向项目“水蚀预报模型研究”(KZCX3-SW-422);国家自然科学基金重点项目“黄土高原小流域分布式水蚀预报模型研究”(40335050);农业部948项目(2003-Z57)
作者简介:郑粉莉(1960- ),女,陕西蓝田人,研究员,博士生导师,主要从事土壤侵蚀过程及预报和土壤侵蚀环境效应评价研究。