Laboratory investigation and simulation of breakthrough curves in karst conduits with pools

Benedict RP (1980) Fundamentals of pipe flow. Wiley, Chichester, UK

Birk S, Geyer T, Liedl R, Sauter M (2005) Process-based interpretation of tracer tests in carbonate aquifers. Ground Water 43(3):381–388

Chatwin PC (1971) On the interpretation of some longitudinal dispersion experiments. J Fluid Mech 48(4):689–702

Chen CX (1995) Groundwater flow model and simulation method in triple media of karstic tube-fissure-pore. Earth Sci 20(4):361–366

De Marsily G (1986) Quantitative hydrogeology: groundwater hydrology for engineers. Academic, New York

De Smedt F, Brevis W, Debels P (2005) Analytical solution for solute transport resulting from instantaneous injection in streams with transient storage. J Hydrol 315:25–39

Dewaide L, Bonniver I, Rochez G, Hallet V (2016) Solute transport in heterogeneous karst systems: dimensioning and estimation of the transport parameters via multi-sampling tracer-tests modeling using the OTIS (one-dimensional transport with inflow and storage) program. J Hydrol 534:567–578

Field MS (2002a) The QTRACER2 program for tracer-breakthrough curve analysis for tracer tests in karstic aquifers and other hydrologic systems. EPA/600/R-02/001, US Environmental Protection Agency, Washington, DC

Field MS (2002b) Efficient hydrologic tracer-test design for tracer-mass estimation and sample-collection frequency, 1: method development. Environ Geol 42:827–838

Field MS, Leij FJ (2012) Solute transport in solution conduits exhibiting multi-peaked breakthrough curves. J Hydrol 440–441:26–35

Field MS, Pinsky PF (2000) A two-region nonequilibrium model for solute transport in solution conduits in karstic aquifers. J Contam Hydrol 44(3):329–351

Ford DC, Williams PW (1989) Karst geomorphology and hydrology. Hyman, London, 601 pp

Geyer T, Birk S, Licha T, Liedl R, Sauter M (2007) Multitracer test approach to characterize reactive transport in karst aquifers. Ground Water 45:36–45

Goldscheider N (2008) A new quantitative interpretation of the long-tail and plateau-like breakthrough curves from tracer tests in the artesian karst aquifer of Stuttgart, Germany. Hydrogeol J 16:1311–1317

Goppert N, Goldscheider N (2008) Solute and colloid transport in karst conduits under low- and high-flow conditions. Ground Water 46:61–68

Hart JR, Guymer I, Sonnenwald F, Stovin VR (2016) Residence time distributions for turbulent, critical, and laminar pipe flow. J Hydraul Eng 142(9):04016024

Hauns M (2000) Modeling tracer and particle transport under turbulent flow conditions in karst conduit structures. Institut für Hydrologie der Universität Freiburg, Freiburg, Germany

Hauns M, Jeannin PY, Atteia O (2001) Dispersion, retardation and scale effect in tracer breakthrough curves in karst conduits. J Hydrol 241(3):177–193

Hubbard EF, Kilpatrick FA, Martens LA, Wilson JF Jr (1982) Measurements of time of travel and dispersion in streams by dye tracing. In: Techniques of Water-Resources Investigations, book 3: applications of hydraulics, chap A9. US Geological Survey, Washington, DC

Jackson TR, Apte SV, Haggerty R (2014) Effect of multiple lateral cavities on stream solute transport under non-Fickian conditions and at the Fickian asymptote. J Hydrol 519:1707–1722

Kazezyılmaz-Alhan CM, Medina MA (2006) Stream solute transport incorporating hyporheic zone processes. J Hydrol 329:26–38

Labat D, Mangin A (2015) Transfer function approach for artificial tracer test interpretation in karstic systems. J Hydrol 529:866–871

Lee SH, Yeo IW, Lee K-K, Detwiler RL (2015) Tail shortening with developing eddies in a rough-walled rock fracture. Geophys Res Lett 42:6340–6347

Magal E, Arbel Y, Caspi S, Glazman H, Greenbaum N, Yechieli Y (2013) Determination of pollution and recovery time of karst springs, an example from a carbonate aquifer in Israel. J Contam Hydrol 145:26–36

Maloszewski P, Zuber A (1989) Mathematical models for interpreting tracer experiments in fissured aquifers: the application of isotope techniques in the study of the hydrology of fractured and fissured rocks. IAEA, Vienna

Maloszewski P, Zuber A (1993) Tracer experiments in fractured rocks: matrix diffusion and the validity of models. Water Resour Res 29(8):2723–2735

Maloszewski P, Harum T, Benischke R (1992) Mathematical modeling of tracer experiments in the karst of Lurbach system. Beitr Hydrogeol 43:116–136

Martin JB, Dean RW (2001) Exchange of water between conduits and matrix in the Floridan aquifer. Chem Geol 179(1):145–165

Martin JL, McCutcheon SC (1998) Hydrodynamics and transport for water quality modeling. Lewis, London

Massei N, Wang HQ, Field MS, Dupont JP, Bakalowicz M, Rodet J (2006) Interpreting tracer breakthrough tailing in a conduit-dominated karstic aquifer. Hydrogeol J 14:849–858

Morales T, Fdez. de Valderrama I, Uriarte JA, Antigüedad I, Olazar M (2007) Predicting travel times and transport characterization in karst conduits by analyzing tracer-breakthrough curves. J Hydrol 334:183–198

Morales T, Uriarte JA, Olazar M, Antigüedad I, Angulo B (2010) Solute transport modeling in karst conduits with slow zones during different hydrologic conditions. J Hydrol 390:182–189

Raven KG, Novakowski KS, Lapcevic PA (1988) Interpretation of field tracer tests of a single fracture using a transient solute storage model. Water Resour Res 24(12):2019–2032

Ronayne MJ (2013) Influence of conduit network geometry on solute transport in karst aquifers with a permeable matrix. Adv Water Resour 56:27–34

Rossier Y, Kiraly L (1992) Effet de la dilution sur la détermination des dispersivités par interprétation des essais de traçage dans les aquifères karstiques [Effect of dilution on the determination of dispersivities by interpretation of tracing tests in karst aquifers]. Bull Centre Hydrogéol Neuchâtel 11:1–15

Runkel RL (1998) One-dimensional transport with inflow and storage (OTIS): a solute transport model for streams and rivers. US Geol Surv Water Resour Invest Rep 98-4018

Shapiro AM, Renken RA, Harvey RW, Zygnerski MR, Metge DW (2008) Pathogen and chemical transport in the karst limestone of the Biscayne aquifer: 2. chemical retention from diffusion and slow advection. Water Resour Res 44(8)

Sudicky EA, Frind EO (1982) Contaminant transport in fractured porous media: analytical solutions for a system of parallel fractures. Water Resour Res 18(6):1634–1642

Taylor GI (1954) The dispersion of matter in turbulent flow through a pipe. Proc R Soc 223(1155):446–468

Toride N, Leij FJ, Van Genuchten MT (1993) A comprehensive set of analytical solutions for nonequilibrium solute transport with first-order decay and zero-order production. Water Resour Res 29(7):2167–2182

Toride N, Leij FJ, Van Genuchten MT (1999) The CXTFIT code (version 2.1) for estimating transport parameters from laboratory or filed tracer experiments. US Salinity Lab, Agricultural Research Service, US Dept. of Agriculture, Riverside, CA

Wang HQ (1987) A linear graphical method for determining hydrodispersive characteristics in tracer experiments with instantaneous injection. J Hydrol 95(1–2):143–154

Wang QJ (1991) The genetic algorithm and its application to calibrating conceptual rainfall–runoff models. Water Resour Res 27(9):2467–2471

Wu Y, Hunkeler D (2013) Hyporheic exchange in a karst conduit and sediment system: a laboratory analog study. J Hydrol 501:125–132

Xu Z, Hu BX, Davis H, Cao J (2015) Simulating long term nitrate-N contamination processes in the Woodville karst plain using CFPv2 with UMT3D. J Hydrol 524:72–88

Zaramella M, Marion A, Lewandowski J, Nützmann G (2016) Assessment of transient storage exchange and advection–dispersion mechanisms from concentration signatures along breakthrough curves. J Hydrol 538:794–801

Zhang W, Boufadel MC (2010) Pool effects on longitudinal dispersion in streams and rivers. J Water Resour Prot 2:960–971