Modeling interbasin groundwater flow in karst areas: Model development, application, and calibration strategy
暂无分享,去创建一个
[1] S. Kanae,et al. Global Hydrological Cycles and World Water Resources , 2006, Science.
[2] Ambro Gieske,et al. Calibration of a semi-distributed hydrological model using discharge and remote sensing data , 2009 .
[3] J. Dietrich,et al. Modification of the SWAT model to simulate regional groundwater flow using a multicell aquifer , 2018 .
[4] Thorsten Wagener,et al. Testing the realism of model structures to identify karst system processes using water quality and quantity signatures , 2013 .
[5] Dennis Trolle,et al. The impact of the objective function in multi-site and multi-variable calibration of the SWAT model , 2017, Environ. Model. Softw..
[6] J. Gunn,et al. A conceptual model for conduit flow dominated karst aquifers , 1986 .
[7] Stephen R. Workman,et al. Hydrologic Modeling of Flow through Sinkholes Located in Streambeds of Cane Run Stream, Kentucky , 2015 .
[8] Maurice E. Tucker,et al. Sequence stratigraphy of carbonate-evaporite basins: models and application to the Upper Permian (Zechstein) of northeast England and adjoining North Sea , 1991, Journal of the Geological Society.
[9] N. B. Bonumà,et al. Multi-variable SWAT model calibration with remotely sensed evapotranspiration and observed flow , 2017 .
[10] R. McColl,et al. Encyclopedia of World Geography , 2005 .
[11] C. Perrin,et al. Improvement of a parsimonious model for streamflow simulation , 2003 .
[12] Vazken Andréassian,et al. How can rainfall‐runoff models handle intercatchment groundwater flows? Theoretical study based on 1040 French catchments , 2007 .
[13] E. Screaton,et al. Conduit Properties and Karstification in the Unconfined Floridan Aquifer , 2004, Ground water.
[14] M. Bakalowicz. Karst groundwater: a challenge for new resources , 2005 .
[15] N P Nikolaidis,et al. Modeling suspended sediment transport and assessing the impacts of climate change in a karstic Mediterranean watershed. , 2015, The Science of the total environment.
[16] John R. Williams,et al. LARGE AREA HYDROLOGIC MODELING AND ASSESSMENT PART I: MODEL DEVELOPMENT 1 , 1998 .
[17] Peter Droogers,et al. Calibration of a distributed hydrological model based on satellite evapotranspiration , 2008 .
[18] Andy Purvis,et al. MODISTools – downloading and processing MODIS remotely sensed data in R , 2014, Ecology and evolution.
[19] K. Abbaspour,et al. Estimating Uncertain Flow and Transport Parameters Using a Sequential Uncertainty Fitting Procedure , 2004 .
[20] T. Mathevet,et al. Confronting surface‐ and groundwater balances on the La Rochefoucauld‐Touvre karstic system (Charente, France) , 2008 .
[21] Richard G. Allen,et al. A Penman for All Seasons , 1986 .
[22] Alfred Bögli,et al. Karst Hydrology and Physical Speleology , 1980 .
[23] D. Ford,et al. Karst Hydrogeology and Geomorphology , 2007 .
[24] K. H. Wedepohl,et al. The isotopic composition of strontium and sulfur in seawater of Late Permian (Zechstein) age , 1991 .
[25] Jim E Freer,et al. Process-based modelling to evaluate simulated groundwater levels and frequencies in a Chalk catchment in south-western England , 2018 .
[26] O. Batelaan,et al. Test of a distributed modelling approach to predict flood flows in the karst Suoimuoi catchment in Vietnam , 2005 .
[27] Jörg Dietrich,et al. Using SWAT for Strategic Planning of Basin Scale Irrigation Control Policies: a Case Study from a Humid Region in Northern Germany , 2016, Water Resources Management.
[28] Raghavan Srinivasan,et al. SWAT: Model Use, Calibration, and Validation , 2012 .
[29] Dwight A. Sangrey,et al. Predicting Ground-water Response to Precipitation , 1984 .
[30] K. Abbaspour,et al. Modelling hydrology and water quality in the pre-alpine/alpine Thur watershed using SWAT , 2007 .
[31] Karim C. Abbaspour,et al. A Guideline for Successful Calibration and Uncertainty Analysis for Soil and Water Assessment: A Review of Papers from the 2016 International SWAT Conference , 2017 .
[32] J. Tóth. A Theoretical Analysis of Groundwater Flow in Small Drainage Basins , 1963 .
[33] Enrico Bertuzzo,et al. Catchment residence and travel time distributions: The master equation , 2011 .
[34] Nicola Fohrer,et al. Assessing the spatial and temporal variations of water quality in lowland areas, Northern Germany , 2012 .
[35] Jeffrey G. Arnold,et al. Soil and Water Assessment Tool Theoretical Documentation Version 2009 , 2011 .
[36] J. Monteith. Evaporation and environment. , 1965, Symposia of the Society for Experimental Biology.
[37] Dieter Meischner,et al. Seasonal variability of Holocene climate: a palaeolimnological study on varved sediments in Lake Jues (Harz Mountains, Germany) , 2008 .
[38] Shakeel Ahmed,et al. Review: Carbonate aquifers and future perspectives of karst hydrogeology in India , 2014, Hydrogeology Journal.
[39] Charles R. Lane,et al. Hydrologic model predictability improves with spatially explicit calibration using remotely sensed evapotranspiration and biophysical parameters , 2018, Journal of hydrology.
[40] J. Arnold,et al. SWAT2000: current capabilities and research opportunities in applied watershed modelling , 2005 .
[41] Marvin E. Jensen,et al. Operational estimates of reference evapotranspiration , 1989 .
[42] Jeffrey G. Arnold,et al. The Soil and Water Assessment Tool: Historical Development, Applications, and Future Research Directions , 2007 .
[43] David G. Tingey,et al. Interbasin flow revisited: The contribution of local recharge to high-discharge springs, Death Valley, CA , 2006 .
[44] J. C. M. Taylor,et al. Upper Permian—Zechstein , 2009 .
[45] J. Nash,et al. River flow forecasting through conceptual models part I — A discussion of principles☆ , 1970 .
[46] S. Seneviratne,et al. Recent decline in the global land evapotranspiration trend due to limited moisture supply , 2010, Nature.
[47] Joseph H. A. Guillaume,et al. Remotely sensed evapotranspiration to calibrate a lumped conceptual model: Pitfalls and opportunities , 2014 .
[48] Peter Droogers,et al. Estimating actual irrigation application by remotely sensed evapotranspiration observations , 2010 .
[49] Thorsten Wagener,et al. Karst water resources in a changing world: Review of hydrological modeling approaches , 2014 .
[50] M. Franchini,et al. Regional scale hydrologic modeling of a karst-dominant geomorphology: The case study of the Island of Crete , 2016 .
[51] Eduard A. Koster,et al. The physical geography of Western Europe , 2005 .
[52] M. White,et al. Advances in water resources assessment with SWAT—an overview , 2015 .
[53] Jörg Dietrich,et al. Verification and Correction of the Hydrologic Routing in the Soil and Water Assessment Tool , 2018, Water.
[54] Simon Stisen,et al. Assessment of regional inter-basin groundwater flow using both simple and highly parameterized optimization schemes , 2019, Hydrogeology Journal.
[55] J. Dietrich,et al. Evaluation of SWAT simulated soil moisture at catchment scale by field measurements and Landsat derived indices , 2017 .
[56] Nico Goldscheider,et al. Methods in karst hydrogeology , 2007 .
[57] Ewald Schnug,et al. Diagnosis of Sulphur Nutrition , 1998 .
[58] Demetris Koutsoyiannis,et al. A multicell karstic aquifer model with alternative flow equations , 2006 .
[59] George P. Karatzas,et al. An integrated framework for the hydrologic simulation of a complex geomorphological river basin , 2010 .
[60] M. S. Bedinger,et al. Interbasin flow in the Great Basin with special reference to the southern Funeral Mountains and the source of Furnace Creek springs, Death Valley, California, U.S. , 2009 .
[61] William B. White,et al. Karst hydrology: recent developments and open questions , 2002 .
[62] N. Goldscheider,et al. Karst groundwater vulnerability mapping: application of a new method in the Swabian Alb, Germany , 2005 .
[63] F. Zwahlen,et al. Water vulnerability assessment in karst environments: a new method of defining protection areas using a multi-attribute approach and GIS tools (EPIK method) , 1999 .
[64] Indrajeet Chaubey,et al. SENSITIVITY ANALYSIS, CALIBRATION, AND VALIDATIONS FOR A MULTISITE AND MULTIVARIABLE SWAT MODEL 1 , 2005 .
[65] Fayçal Bouraoui,et al. Hydrologic and geochemical modeling of a karstic Mediterranean watershed , 2013 .
[66] M. Böttcher,et al. The Stable Isotopic Geochemistry of the Sulfur and Carbon Cycles in a Modern Karst Environment. , 1999, Isotopes in environmental and health studies.
[67] T. roje-Bonacci,et al. Karst flash floods: an example from the Dinaric karst (Croatia) , 2006 .
[68] Andreas Hartmann,et al. On the value of water quality data and informative flow states in karst modelling , 2017 .
[69] Sjoerd E. A. T. M. van der Zee,et al. Chloride circulation in a lowland catchment and the formulation of transport by travel time distributions , 2013 .
[70] Michael E. Barrett,et al. A parsimonious model for simulating flow in a karst aquifer , 1997 .
[71] Roberto Anaya,et al. A Lumped Parameter Model for the Edwards Aquifer , 1993 .
[72] Thorsten Wagener,et al. Modeling spatiotemporal impacts of hydroclimatic extremes on groundwater recharge at a Mediterranean karst aquifer , 2014 .
[73] Hoshin Vijai Gupta,et al. Decomposition of the mean squared error and NSE performance criteria: Implications for improving hydrological modelling , 2009 .
[74] M. G. Bos,et al. Multi-variable calibration of a semi-distributed hydrological model using streamflow data and satellite-based evapotranspiration , 2013 .
[75] Michael E. Barrett,et al. Can we simulate regional groundwater flow in a karst system using equivalent porous media models? Case study, Barton Springs Edwards aquifer, USA , 2003 .
[76] P. Lamoreaux,et al. Springs and bottled waters of the world : ancient history, source, occurence, quality and use , 2001 .
[77] Lu Zhang,et al. Use of Remotely Sensed Actual Evapotranspiration to Improve Rainfall–Runoff Modeling in Southeast Australia , 2009 .