Molénat J, Gascuel-Odoux C, Davy P, et al. How to model shallow water-table depth variations: the case of the Kervidy-Naizin catchment, France. Hydrological Processes, 2005, 19(4): 901-920.
[2]
Schuurmans J, Bierkens M. Effect of spatial distribution of daily rainfall on interior catchment response of a distributed hydrological model. Hydrology and Earth System Sciences, 2007, 11(2): 677-693.
[3]
Ludwig R, Taschner S, Mauser W. Modelling floods in the Ammer catchment: limitations and challenges with a coupled meteo-hydrological model approach. Hydrology and Earth System Sciences, 2003, 7(6): 833-847.
[4]
Shrestha R, Bárdossy A, Rode M. A hybrid deterministic -fuzzy rule based mode for catchment scale nitrate dynamics. Journal of Hydrology, 2007, 342(1-2): 143-156.
[5]
Daldorph P, Lees M, Wheater H, et al. Integrated lake and catchment phosphorus mode-A eutrophication management tool. I: Model theory. Journal of the Chartered Institution of Water and Environmental Management, 2001, 15(3): 174-181.
[6]
Haydon S, Deletic A. Model output uncertainty of a coupled pathogen indicator-hydrologic catchment model due to input data uncertainty. Environmental Modeling & Software, 2009, 24(3): 322-328.
[7]
Fiener P, Govers G, Oost K. Evaluation of a dynamic multi-class sediment transport model in a catchment under soil conservation agriculture. Earth Surface Processes and Landforms, 2008, 33(11): 1639-1660.
[8]
Lufafa A, Tenywa M, Isabirye M, et al. Prediction of soil erosion in a Lake Victoriabasin catchment using a GIS-based Universal Soil Loss model. Agricultural Systems, 2003, 76(3): 883-894.
[9]
Maréchal D, Holman I. Development and application of a soil classification-based conceptual catchment-scale hydrological model. Journal of Hydrology, 2005, 312(1-4): 277-293.
[10]
Hessel R, Tenge A. A pragmatic approach to modelling soil and water conservation measures with a catchment scale erosion model. Catena, 2008, 74(2): 119-126.
[11]
Pei T, Liu J, Li J, et al. A modified subsurface stormflow model of hillsides in forest catchment. Hydrological Processes, 2005, 19(13): 2609-2624.
[12]
Eckhardt K, Arnold G. Automatic calibration of a distributed catchment model. Journal of Hydrology, 2001, 251 (1-4): 103-109.
[13]
Merz S, Bl?schl G. Regionalisation of catchment model parameter. Journal of Hydrology, 2004, 287(1-2): 95-123.
[14]
Francos, Elorza F, Bouraoui F, et al. Sensitivity analysis of distributed environmental simulation models: understanding the model behaviour in hydrological studies at the catchment scale. Reliability Engineering and System Safety, 2003, 79(2): 205-218.
[15]
Haydon S, Deletic A. Development of a coupled pathogen-hydrologic catchment model. Journal of Hydrology, 2006, 328(3-4): 467-480.
[16]
Davis H, Vertessy R, Silberstein R. The sensitivity of a catchment model to soil hydraulic properties obtained by using different measurement techniques. Hydrological Processes, 1999, 13(5): 677-688.
International Workshop on Status and Perspectives of Hydrology in Small Basins[M]. Goslar-hahnenklee, Federal Republic of Germany. 2009, 3. Ihp&HWRP
[42]
Baudena M, D'Andrea F, Provenzale A. A model for soil-vegetation-atmosphere interactions in water-limited ecosystems. Water Resource Research, DOI: 10.1029/2008WR007172.
[43]
VanderVelde Y, deRooij GH, Torfs PJJF. Catchment-scale non-linear groundwater-surface water interactions in densely drained lowland catchments. Hydrology and Earth System Sicence, 2009, 13(10): 1867-1885.
[44]
Sun G, Amatya D M, McNulty S G, et al. Climate change impacts on the hydrology and productivity of a pine plantation . Journal of the American Water Resources Association, 2000, 36(2): 367-374.
[45]
Germer S, Neill C, Vetter T, et al. Implications of long-term land-use change for the hydrology and solute budgets of small catchments in Amazonia. Journal of Hydrology, 2009, 364(3-4): 349-363.
[46]
Sivapalan M, Takeuchi K, Franks SW, et al. IAHS decade on Predictions in Ungauged Basins (PUB), 2003-2012: Shaping an exciting future for the hydrological sciences. Hydrological Sciences Journal / Journal des Sciences Hydrologiques, 2003, 48(6): 857-880.
[47]
McKnight D M, Bencala K E. The Chemistry of Iron, Aluminum, and Dissolved Organic Material in Three Acidic, Metal-Enriched, Mountain Streams, as Controlled by Watershed and in-Stream Processes. Water Resource Research, 1990, 26(12): 3087-3100.
[48]
Gambillara R, Terrana S, Monticelli D, et al. Chemical features of the springs and correlations with faults in north-western area of Como Lake basin (Northern Italy). Proceedings of the“European Geosciences Union General Assembly”Vienna, Austria Center Vienna, Austria, 2005: 24-29.
[49]
Raczak J, Zelazny M. Diurnal fluctuation in stream-water chemical composition in small Carpathian Foothills’ catchments (Southern Polland). Proceedings of the“Progress in surface and subsurface water studies at the plot and small basin scale”Turin, Italy, 200-203, October 13-17, 2004.
[50]
Mullinger N J, Pates J M, Binley A M, et al. Controls on the spatial and temporal variability of Rn-222 in riparian groundwater in a lowland Chalk catchment. Journal of Hydrology, 2009, 376(1-2): 58-69.
[51]
Yu G A, Wang Z Y, Zhang K, et al. Effect of incoming sediment on the transport rate of bed load in mountain streams. International Journal of Sediment Research, 2009, 24(3): 260-273.
[52]
Schlunegger F, Badoux A, McArdell B W, et al. Limits of sediment transfer in an alpine debris-flow catchment, Illgraben, Switzerland. Quaternary Science Reviews, 2009, 28(11-12): 1097-1105.
[53]
Manley R. The soil moisture component of mathematical catchment simulation models. Journal of Hydrology, 1977, 35(3-4): 341-356.
[54]
Chiew F, Whetton P, McMahon T, et al. Simulation of the impacts of climate change on runoff and soil moisture in Australian catchments. Journal of Hydrology, 1995, 167(1-4): 121-147.
[55]
Fitzjohn C, Ternan J, Williams A. Soil moisture variability in a semi-arid gully catchment: implications for runoff and erosion control. Catena, 1998, 32(1): 55-70.
[56]
Schuurmans J, Bierkens M. Effect of spatial distribution of daily rainfall on interior catchment response of a distributed hydrological model. Hydrology and Earth System Sciences, 2007, 11(2): 677-693.
[57]
Evans J, Jakeman A. Development of a simple, catchment-scale, rainfall evapotranspiration-runoff mode. Environmental Modelling & Software, 1998, 13(3-4): 385-393.
[58]
Croke B, Jakeman A. A catchment moisture deficit module for the IHACRES rainfall runoff model. Environmental Modeling & Software, 2004, 19(1): 1-5.
[59]
Molénat J, Gascuel-Odoux C, Davy P, et al. How to model shallow water-table depth variations: the case of the Kervidy-Naizin catchment, France. Hydrological Processes, 2005, 19(4): 901-920.
[60]
Schuurmans J, Bierkens M. Effect of spatial distribution of daily rainfall on interior catchment response of a distributed hydrological model. Hydrology and Earth System Sciences, 2007, 11(2): 677-693.
[61]
Ludwig R, Taschner S, Mauser W. Modelling floods in the Ammer catchment: limitations and challenges with a coupled meteo-hydrological model approach. Hydrology and Earth System Sciences, 2003, 7(6): 833-847.
[62]
Shrestha R, Bárdossy A, Rode M. A hybrid deterministic –fuzzy rule based mode for catchment scale nitrate dynamics. Journal of Hydrology, 2007, 342(1-2): 143-156.
[63]
Daldorph P, Lees M, Wheater H, et al. Integrated lake and catchment phosphorus mode-A eutrophication management tool. I: Model theory. Journal of the Chartered Institution of Water and Environmental Management, 2001, 15(3): 174-181.
[64]
Haydon S, Deletic A. Model output uncertainty of a coupled pathogen indicator-hydrologic catchment model due to input data uncertainty. Environmental Modeling & Software, 2009, 24(3): 322-328.
[65]
Fiener P, Govers G, Oost K. Evaluation of a dynamic multi-class sediment transport model in a catchment under soil conservation agriculture. Earth Surface Processes and Landforms, 2008, 33(11): 1639-1660.
[66]
Lufafa A, Tenywa M, Isabirye M, et al. Prediction of soil erosion in a Lake Victoriabasin catchment using a GIS-based Universal Soil Loss model. Agricultural Systems, 2003, 76(3): 883-894.
[67]
Maréchal D, Holman I. Development and application of a soil classification-based conceptual catchment-scale hydrological model. Journal of Hydrology, 2005, 312(1-4): 277-293.
[68]
Hessel R, Tenge A. A pragmatic approach to modelling soil and water conservation measures with a catchment scale erosion model. Catena, 2008, 74(2): 119-126.
[69]
Pei T, Liu J, Li J, et al. A modified subsurface stormflow model of hillsides in forest catchment. Hydrological Processes, 2005, 19(13): 2609-2624.
Zhang J, Zhuang J, Su J, et al. Development of GIS-based FUSLE model in a Chinese fir forest sub-catchment with a focus on the litter in the Dabie Mountains, China. Forest Ecology and Management, 2008, 255(7): 2782-2789.
[73]
Immerzeel W W, Gaur A, Zwart S J. Integrating remote sensing and a process-based hydrological model to evaluate water use and productivity in a south Indian catchment. Agricultural Water Management, 2008, 95(1): 11-24.
[74]
Thiessen K, Sazykina T, Apostoae A, et al. Model testing using data on 137Cs from Chernobyl fallout in the Iput River catchment area of Russia. Journal of Environmental Radioactivity, 2005, 84(2): 225-244.
[75]
H?rmann G, Zhang X, Fohrer N. Comparison of a simple and a spatially distributed hydrologic model for the simulation of a lowland catchment in Northern Germany. Ecological Modeling, 2007, 209(1): 21-28.
[76]
Varanou E, Gkouvatsou E, Baltas E, et al. Quantity and Quality Integrated Catchment Modeling under Climate Change with use of Soil andWater Assessment Tool Model. Journal of Hydrologic Engineering, 2002, 7(3): 228-254.
Yu J J, Yang C, Liu C M, et al. Slope runoff study in situ using rainfall simulator in mountainous area of North China. Journal of Geographical Sciences, 2009, 19(4): 461-470.
International Workshop on Status and Perspectives of Hydrology in Small Basins[M]. Goslar-hahnenklee, Federal Republic of Germany. 2009, 3. Ihp&HWRP
[111]
Baudena M, D'Andrea F, Provenzale A. A model for soil-vegetation-atmosphere interactions in water-limited ecosystems. Water Resource Research, DOI: 10.1029/2008WR007172.
[112]
VanderVelde Y, deRooij GH, Torfs PJJF. Catchment-scale non-linear groundwater-surface water interactions in densely drained lowland catchments. Hydrology and Earth System Sicence, 2009, 13(10): 1867-1885.
[113]
Sun G, Amatya D M, McNulty S G, et al. Climate change impacts on the hydrology and productivity of a pine plantation . Journal of the American Water Resources Association, 2000, 36(2): 367-374.
[114]
Germer S, Neill C, Vetter T, et al. Implications of long-term land-use change for the hydrology and solute budgets of small catchments in Amazonia. Journal of Hydrology, 2009, 364(3-4): 349-363.
[115]
Sivapalan M, Takeuchi K, Franks SW, et al. IAHS decade on Predictions in Ungauged Basins (PUB), 2003-2012: Shaping an exciting future for the hydrological sciences. Hydrological Sciences Journal / Journal des Sciences Hydrologiques, 2003, 48(6): 857-880.
[116]
McKnight D M, Bencala K E. The Chemistry of Iron, Aluminum, and Dissolved Organic Material in Three Acidic, Metal-Enriched, Mountain Streams, as Controlled by Watershed and in-Stream Processes. Water Resource Research, 1990, 26(12): 3087-3100.
[117]
Gambillara R, Terrana S, Monticelli D, et al. Chemical features of the springs and correlations with faults in north-western area of Como Lake basin (Northern Italy). Proceedings of the“European Geosciences Union General Assembly”Vienna, Austria Center Vienna, Austria, 2005: 24-29.
[118]
Raczak J, Zelazny M. Diurnal fluctuation in stream-water chemical composition in small Carpathian Foothills’ catchments (Southern Polland). Proceedings of the“Progress in surface and subsurface water studies at the plot and small basin scale”Turin, Italy, 200-203, October 13-17, 2004.
[119]
Mullinger N J, Pates J M, Binley A M, et al. Controls on the spatial and temporal variability of Rn-222 in riparian groundwater in a lowland Chalk catchment. Journal of Hydrology, 2009, 376(1-2): 58-69.
[120]
Yu G A, Wang Z Y, Zhang K, et al. Effect of incoming sediment on the transport rate of bed load in mountain streams. International Journal of Sediment Research, 2009, 24(3): 260-273.
[121]
Schlunegger F, Badoux A, McArdell B W, et al. Limits of sediment transfer in an alpine debris-flow catchment, Illgraben, Switzerland. Quaternary Science Reviews, 2009, 28(11-12): 1097-1105.
[122]
Manley R. The soil moisture component of mathematical catchment simulation models. Journal of Hydrology, 1977, 35(3-4): 341-356.
[123]
Chiew F, Whetton P, McMahon T, et al. Simulation of the impacts of climate change on runoff and soil moisture in Australian catchments. Journal of Hydrology, 1995, 167(1-4): 121-147.
[124]
Fitzjohn C, Ternan J, Williams A. Soil moisture variability in a semi-arid gully catchment: implications for runoff and erosion control. Catena, 1998, 32(1): 55-70.
[125]
Schuurmans J, Bierkens M. Effect of spatial distribution of daily rainfall on interior catchment response of a distributed hydrological model. Hydrology and Earth System Sciences, 2007, 11(2): 677-693.
[126]
Evans J, Jakeman A. Development of a simple, catchment-scale, rainfall evapotranspiration-runoff mode. Environmental Modelling & Software, 1998, 13(3-4): 385-393.
[127]
Croke B, Jakeman A. A catchment moisture deficit module for the IHACRES rainfall runoff model. Environmental Modeling & Software, 2004, 19(1): 1-5.
[128]
Hansen J, Ernstsen V, Refsgaard J, et al. Field scale heterogeneity of redox conditions in till-upscaling to a catchment nitrate model. Hydrogeology Journal, 2008, 16(7): 1251-1266.
[129]
Zhang J, Zhuang J, Su J, et al. Development of GIS-based FUSLE model in a Chinese fir forest sub-catchment with a focus on the litter in the Dabie Mountains, China. Forest Ecology and Management, 2008, 255(7): 2782-2789.
[130]
Immerzeel W W, Gaur A, Zwart S J. Integrating remote sensing and a process-based hydrological model to evaluate water use and productivity in a south Indian catchment. Agricultural Water Management, 2008, 95(1): 11-24.
[131]
Thiessen K, Sazykina T, Apostoae A, et al. Model testing using data on 137Cs from Chernobyl fallout in the Iput River catchment area of Russia. Journal of Environmental Radioactivity, 2005, 84(2): 225-244.
[132]
H?rmann G, Zhang X, Fohrer N. Comparison of a simple and a spatially distributed hydrologic model for the simulation of a lowland catchment in Northern Germany. Ecological Modeling, 2007, 209(1): 21-28.
[133]
Varanou E, Gkouvatsou E, Baltas E, et al. Quantity and Quality Integrated Catchment Modeling under Climate Change with use of Soil andWater Assessment Tool Model. Journal of Hydrologic Engineering, 2002, 7(3): 228-254.
Yu J J, Yang C, Liu C M, et al. Slope runoff study in situ using rainfall simulator in mountainous area of North China. Journal of Geographical Sciences, 2009, 19(4): 461-470.
Eckhardt K, Arnold G. Automatic calibration of a distributed catchment model. Journal of Hydrology, 2001, 251 (1-4): 103-109.
[147]
Merz S, Bl?schl G. Regionalisation of catchment model parameter. Journal of Hydrology, 2004, 287(1-2): 95-123.
[148]
Francos, Elorza F, Bouraoui F, et al. Sensitivity analysis of distributed environmental simulation models: understanding the model behaviour in hydrological studies at the catchment scale. Reliability Engineering and System Safety, 2003, 79(2): 205-218.
[149]
Haydon S, Deletic A. Development of a coupled pathogen-hydrologic catchment model. Journal of Hydrology, 2006, 328(3-4): 467-480.
[150]
Davis H, Vertessy R, Silberstein R. The sensitivity of a catchment model to soil hydraulic properties obtained by using different measurement techniques. Hydrological Processes, 1999, 13(5): 677-688.
[151]
Hansen J, Ernstsen V, Refsgaard J, et al. Field scale heterogeneity of redox conditions in till-upscaling to a catchment nitrate model. Hydrogeology Journal, 2008, 16(7): 1251-1266.
