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Hydrogeology Journal

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24.02.2017 | Paper

A coupled groundwater-flow-modelling and vulnerability-mapping methodology for karstic terrain management

verfasst von: Konstantina P. Kavouri, George P. Karatzas, Valérie Plagnes

Erschienen in: Hydrogeology Journal | Ausgabe 5/2017

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Abstract

A coupled groundwater-flow-modelling and vulnerability-mapping methodology for the management of karst aquifers with spatial variability is developed. The methodology takes into consideration the duality of flow and recharge in karst and introduces a simple method to integrate the effect of temporal storage in the unsaturated zone. In order to investigate the applicability of the developed methodology, simulation results are validated against available field measurement data. The criteria maps from the PaPRIKa vulnerability-mapping method are used to document the groundwater flow model. The FEFLOW model is employed for the simulation of the saturated zone of Palaikastro-Chochlakies karst aquifer, in the island of Crete, Greece, for the hydrological years 2010–2012. The simulated water table reproduces typical karst characteristics, such as steep slopes and preferred drain axes, and is in good agreement with field observations. Selected calculated error indicators—Nash-Sutcliffe efficiency (NSE), root mean squared error (RMSE) and model efficiency (E′)—are within acceptable value ranges. Results indicate that different storage processes take place in different parts of the aquifer. The north-central part seems to be more sensitive to diffuse recharge, while the southern part is affected primarily by precipitation events. Sensitivity analysis is performed on the parameters of hydraulic conductivity and specific yield. The methodology is used to estimate the feasibility of artificial aquifer recharge (AAR) at the study area. Based on the developed methodology, guidelines were provided for the selection of the appropriate AAR scenario that has positive impact on the water table.

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Andelman J, Bauwer H, Charbeneau R, Christman R, Crook J, Fan A, Yates M (1994) Groundwater recharge using waters of impaired quality. Natl. Academy Press, Washington, DC

Bakalowicz M (2005) Karst groundwater: a challenge for new resources. Hydrogeol J 13(1):148–160CrossRef

Bauer S, Liedl R, Sauter M (2005) Modeling the influence of epikarst evolution on karst aquifer genesis: a time-variant recharge boundary condition for joint karst-epikarst development. Water Resour Res 41, W09416. doi:10.1029/2004WR003321 CrossRef

Birk S, Liedl R, Sauter M (2006) Karst spring responses examined by process-based modeling. Ground Water 44(6):832–836CrossRef

Bouwer H (2002) Artificial recharge of groundwater: hydrogeology and engineering. Hydrogeol J 10(1):121–142CrossRef

Charlier JB, Bertrand C, Mudry J (2012) Conceptual hydrogeological model of flow and transport of dissolved organic carbon in a small Jura karst system. J Hydrol 460:52–64CrossRef

Chen Z, Goldscheider N (2014) Modeling spatially and temporally varied hydraulic behavior of a folded karst system with dominant conduit drainage at catchment scale, Hochifen-Gottesacker. Alps J Hydrol 514:41–52CrossRef

Dafny E, Burg A, Gvirtzman H (2010) Effects of Karst and geological structure on groundwater flow: the case of Yarqon-Taninim Aquifer, Israel. J Hydrol 389:260–275CrossRef

Daher W, Pistre S, Kneppers A, Bakalowicz M, Najem W (2011) Karst and artificial recharge: theoretical and practical problems—a preliminary approach to artificial recharge assessment. J Hydrol 408:189–202CrossRef

de Rooij R, Perrochet P, Graham W (2013) From rainfall to spring discharge: coupling conduit flow, subsurface matrix flow and surface flow in karst systems using a discrete-continuum model. Adv Water Resour 61:29–41

Diersch HJG (2013) FEFLOW finite element subsurface flow and transport simulation system. User’s manual/reference manual/white papers, Release 6.2. WASY, Berlin

Dorfliger N, Plagnes V (2009) Cartographie de la vulnérabilité des aquifères karstiques guide méthodologique de la méthode PaPRIKa [Mapping the vulnerability of karst aquifers: guidelines of the method PaPRIKa]. Report BRGM RP-57527-FR, BRGM, Orleans, France, 100 pp

Fleury P, Plagnes V, Bakalowicz M (2007) Modelling of the functioning of karst aquifers with a reservoir model: application to Fontaine de Vaucluse (South of France). J Hydrol 345(1):38–49CrossRef

Ford D, Williams PW (2007) Karst hydrogeology and geomorphology. Wiley, Chichester, UK

Goldscheider N, Drew DP (2007) Methods in karst hydrogeology. Taylor and Francis, London

Hugman R, Stigter T, Monteiro JP, Nunes L (2012) Influence of aquifer properties and the spatial and temporal distribution of recharge and abstraction on sustainable yields in semi-arid regions. Hydrol Process 26:2791–280. doi:10.1002/hyp.8353 CrossRef

Huneau F, Jaunat J, Kavouri K, Plagnes V, Rey F, Dörfliger N (2013) Intrinsic vulnerability mapping for small mountains karst aquifers, implementation of the new PaPRIKa method to Western Pyrenees (France). Eng Geol 161:81–93CrossRef

Institute of Geology and Mineral Exploration of Greece (1959) Geological map of Greece. Map Sheet Ziros, scale 1:50.000. IGME, Athens

Institute of Geology and Mineral Exploration of Greece (2005) Hydrogeological study of the Prefecture of Lassithi. Report IGME, IGME, Athens, 243 pp

Jeannin PY (2001) Modeling flow in phreatic and epiphreatic karst conduits in the Holloch Cave (Muotatal, Switzerland). Water Resour Res 37:191–200CrossRef

Jukić D, Denić-Jukić V (2009) Groundwater balance estimation in karst by using a conceptual rainfall–runoff model. J Hydrol 373(3–4):302–315

Kavouri K, Karatzas GP (2016) Integrating diffuse and concentrated recharge in karst models. Water Resour Manag. doi:10.1007/s11269-016-1528-y

Kavouri K, Plagnes V, Tremoulet J, Dörfliger N, Rejiba F, Marchet P (2011) PaPRIKa: a method for estimating karst resource and source vulnerability: application to the Ouysse karst system (southwest France). Hydrogeol J 19:339–353. doi:10.1007/s10040-010-0688-8 CrossRef

Kessler H (1965) Water balance investigation in the karstic region of Hungary. Proc. Assoc. Int. Hydrogeol. Sci. (A.I.H.S.), UNESCO Symp. on Hydrology of Fractured Rocks, Dubrovnik, Croatia, July 1965, pp 90–105

Király L (1998) Modelling karst aquifers by the combined discrete channel and continuum approach. Bull Centre Hydrogéol 1998(16):77–98

Király L (2002) Karstification and groundwater flow. In: Proc. of the conference Evolution of Karst: Prekarst to Cessation. Zalozba ZRC, Postojna-Ljubljana, Slowenia, pp 155–190

Ladouche B, Marechal JC, Dorfliger N (2014) Semi-distributed lumped model of a karst system under active management. J Hydrol 509:215–230CrossRef

Le Moine N, Andréassian V, Mathevet T (2008) Confronting surface-and groundwater balances on the La Rochefoucauld-Touvre karstic system (Charente, France). Water Resour Res 44(3), W03403. doi:10.1029/2007WR005984 CrossRef

Liedl R, Sauter M, Hückinghaus D, Clemens T, Teutsch G (2003) Simulation of the development of karst aquifers using a coupled continuum pipe flow model. Water Resour Res 39(3):1057. doi:10.1029/2001WR001206 CrossRef

Mangin A (1975) Contribution à l’étude hydrodynamique des aquifères karstiques [Contribution to the hydrodynamic study of karstic aquifers]. PhD Thesis, Université de Dijon, France, 422 pp

Martínez-Santos P, Andreu JM (2010) Lumped and distributed approaches to model natural recharge in semiarid karst aquifers. J Hydrol 388(3–4):389–398CrossRef

Moriasi DN, Arnold JG, Van Liew MW, Bingner RL, Harmel RD, Veith TL (2007) Model evaluation guidelines for systematic quantification of accuracy in watershed simulations. Trans ASABE 50(3):885–900CrossRef

Papanikolaou D, Vassilakis E (2010) Thrust faults and extensional detachment faults in Cretan tectono-stratigraphy: implications for Middle Miocene extension. Tectonophysics 488:233–247CrossRef

Perrin J, Jeannin PY, Zwahlen F (2003) Epikarst storage in a karst aquifer: a conceptual model based on isotopic data—Milandre test site, Switzerland. J Hydrol 279:106–124CrossRef

Quinn J, Tomasko D, Kuiper A (2006) Modeling complex flow in karst aquifer. Sediment Geol 184:343–351CrossRef

Scanlon BR, Mace RE, Barrett ME, Smith B (2003) Can we simulate regional groundwater flow in a karst system using equivalent porous media models? Case study, Barton Springs Edwards aquifer, USA. J Hydrol 276(1):137–158CrossRef

Soulios G (1984) Infiltration efficace dans le karst hellénique [Effective infiltration into Greek karst]. J Hydrol 75:343–356CrossRef

Teutsch G, Sauter M (1991) Groundwater modeling in karst terranes: scale effects, data acquisition and field validation. Proc. 3rd Conf. on Hydrogeology, Ecology, Monitoring and Management of Ground Water in Karst Terranes. Nashville, TN, December 1991, pp 17–38

Teutsch G, Sauter M (1998) Distributed parameter modelling approaches in karst-hydrological investigations. Bull Hydrogeol 16:99–109

Tritz S, Guinot V, Joudre H (2011) Modelling the behavior of a karst system catchment using non-liner hysteretic conceptual model. J Hydrol 397:250–262CrossRef

Xanke J, Jourde H, Liesch T, Goldscheider N (2016) Numerical long-term assessment of managed aquifer recharge from a reservoir into a karst aquifer in Jordan. J Hydrol 540:603–614CrossRef

Titel: A coupled groundwater-flow-modelling and vulnerability-mapping methodology for karstic terrain management
verfasst von: Konstantina P. Kavouri
George P. Karatzas
Valérie Plagnes
Publikationsdatum: 24.02.2017
Verlag: Springer Berlin Heidelberg
Erschienen in: Hydrogeology Journal / Ausgabe 5/2017
Print ISSN: 1431-2174
Elektronische ISSN: 1435-0157
DOI: https://doi.org/10.1007/s10040-017-1548-6

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