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Hydrogeology Journal
Erschienen in: Hydrogeology Journal 7/2013

01.11.2013 | Paper

Analysis of subsurface mound spring connectivity in shale of the western margin of the Great Artesian Basin, South Australia

verfasst von: Todd Halihan, Andrew Love, Mark Keppel, Volmer Berens

Erschienen in: Hydrogeology Journal | Ausgabe 7/2013

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Abstract

Mound springs provide the primary discharge mechanism for waters of the western margin of the Great Artesian Basin (GAB), Australia. Though these springs are an important resource in an arid environment, their hydraulics as they discharge from shale are poorly defined. The springs can include extensive spring tails (groundwater-dependent wetlands) and hundreds of springs in a given spring complex. Electrical resistivity imaging (ERI) was used to evaluate spring subsurface hydraulic-connectivity characteristics at three spring complexes discharging through the Bulldog Shale. The results demonstrate that fresher GAB water appears as resistors in the subsurface at these sites, which are characterized by high-salinity conditions in the shallow subsurface. Using an empirical method developed for this work, the ERI data indicate that the spring complexes have multiple subsurface connections that are not always easily observed at the surface. The connections are focused along structural deformation in the shale allowing fluids to migrate through the confining unit. The ERI data suggest the carbonate deposits that the springs generate are deposited on top of the confining unit, not precipitated in the conduit. The data also suggest that spring-tail ecosystems are not the result of a single discharge point, but include secondary discharge points along the tail.
Vorheriger Artikel Hydrogeologic-structure and groundwater-movement imaging in tideland using electrical sounding resistivity: a case study on the Ariake Sea coast, southwest Japan
Nächster Artikel Quantifying time lag of epikarst-spring hydrograph response to rainfall using correlation and spectral analyses

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Literatur
Ah Chee D (2002) Indigenous people’s connection with Kwatye (water) in the Great Artesian Basin. Environ South Australia 9(1):6
Aldam R, Kuang KS (1988) An investigation of structures controlling discharge of spring waters in the South Western Great Artesian Basin. Rept. Bk. 88/4. Department of Mines and Energy, Adelaide, Australia
Berry KA, Armstrong D (1995) Hydrogeological investigation and numerical modeling, Lake Eyre Region, Great Artesian Basin. WMC, Adelaide, Australia
Cobb MA (1975) Sampling and measurement of mound springs, Great Artesian Basin, South Australia. Progress report no. 2, Maree, Curdimurka and Billa Kalina sheets. Open file report, Department of Mines and Energy, South Australia, Geological Survey, Engineering Division, Adelaide, Australia
Crossey LJ, Fischer TP, Patchett PJ, Karlstrom KE, Hilton DR, Newell DL, Huntoon P, Reynolds AC, de Leeuw GAM (2006) Dissected hydrologic system at the Grand Canyon: interaction between deeply derived fluids and plateau aquifer waters in modern springs and travertine. Geology. doi:10.​1130/​G22057.​1
Demanet D, Renardy F, Vanneste K, Jongmans D, Camelbeeck T, Meghraoui M (2001) The use of geophysical prospecting for imaging active faults in the Roer Graben, Belgium. Geophysics 66(1):78–89CrossRef
Drexel JF, Preiss WV (1995) The geology of South Australia, vol 2: the Phanerozoic. Bulletin 54, South Australia Geological Survey, Adelaide, Australia
Habermehl MA (1980) The Great Artesian Basin, Australia. BMR J Aust Geol Geophys 5:9–38
Habermehl MA (1982) Springs in the Great Artesian Basin: their origin and nature. Report 235, Bureau of Mineral Resources, Geology and Geophysics, Canberra, Australia
Habermehl MA (1986) Mound Spring deposits of the Great Artesian Basin. Earth Resources in Time and Space: 8th Geological Convention. Peacock, Adelaide, Australia
Halihan T, Fenstemaker T (2004) Proprietary electrical resistivity imaging method, 20th edn. Oklahoma State University Office of Intellectual Property, Stillwater, OK
Halihan T, Love A, Sharp JM Jr (2005) Identifying connections in a fractured rock aquifer using ADFTs. Ground Water 43(3):327–335CrossRef
Hancock PL, Chalmers RML, Altunel E, Cakir Z (1999) Travitonics: using travertines in active fault studies. J Struc Geol 21(8–9):903–916CrossRef
James BR, Freeze RA (1993) The worth of data in predicting aquitard continuity in hydrogeological design. Water Resour Res. doi:10.​1029/​93wr00547
Karlstrom KE, Keppel MN, Love AJ, Crossey L (2013) Chapter 4: Structural and tectonic history, chap 4. In: Keppel MN, Love AJ, Karlstrom KE, Priestley S (eds) Hydrogeological framework of the western margin of the great artesian basin. National Water Commission, Canberra, Australia
Keppel MN, Clarke JDA, Halihan T, Love A, Werner AD (2010) The hydrochemistry of selected mound spring environments, Lake Eyre South region, Great Artesian Basin, South Australia, Groundwater 2010. IAH, National Convention Centre, Canberra, Australia
Keppel MN, Clarke JDA, Halihan T, Love AJ, Werner AD (2011) Mound springs in the arid Lake Eyre South region of South Australia: a new depositional tufa model and its controls. Sedim Geol 240:55–70CrossRef
Keppel M, Wohling D, Fulton S, Sampson L, Karlstrom K, Nelson G, Ransley T, Love A (2012) Summary of hydrogeology and hydrostratigraphy, chap 3. In: Keppel MN, Love AJ, Karlstrom KE, Priestley S (eds) Hydrogeological framework of the Western Margin of the Great Artesian Basin, Australia. National Water Commission, Canberra, Australia
Krieg GW, Alexander E, Rogers PA (1995) Eromanga Basin. In: Drexel JF, Preiss W (eds) The geology of South Australia. Geological Survey of South Australia, Adelaide, Australia, pp 101–105
La Pointe PR, Hudson JA (1985) Characterization and interpretation of rock mass joint patterns. Geol Soc Am Spec Pap 199
Le Borgne T, Bour O, Riley MS, Gouze P, Pezard PA, Belghoul A, Lods G, Le Provost R, Greswell RB, Ellis PA, Isakov E, Last BJ (2007) Comparison of alternative methodologies for identifying and characterizing preferential flow paths in heterogeneous aquifers. J Hydrol. doi:10.​1016/​j.​jhydrol.​2007.​07.​007
Moore RD (2004) Introduction to salt dilution gauging for streamflow measurement: part 1. Watersh Manag Bull 7(4):20–23
Moore RD (2005) Slug injection using salt in solution. Watersh Manag Bull 8(2):1–6
Murphy NP, Adams M, Austin AD (2009) Independent colonization and extensive cryptic speciation of freshwater amphipods in the isolated groundwater springs of Australia’s Great Artesian Basin. Mol Ecol. doi:10.​1111/​j.​1365-294X.​2008.​04007.​x
Ponder W F (2002) Desert Springs of the Australian Great Artesian Basin. In: Sada D W, Sharpe S E (eds) Spring-fed wetlands: important scientific and cultural resources of the Intermountain Region. Desert Research Institute, Las Vegas, NV
Prescott JR, Habermehl MA (2008) Luminescence dating of spring mound deposits in the southwestern Great Artesian Basin, northern South Australia. Aust J Earth Sci 55(2):167–181CrossRef
Radke BM, Ferguson J, Cresswell RG, Ransley TR, Habermehl MA (2000) Hydrochemistry and implied hydrodynamics of the Cadna-owie-Hooray Aquifer, Great Artesian Basin, Australia. Bureau of Rural Sciences, Canberra, Australia, 232 pp
Sprigg RC (1957) The Great Artesian Basin in South Australia. J Geol Soc Aust 5(2):88–101CrossRef
Warner NR, Kresse TM, Hays PD, Down A, Karr JD, Jackson RB, Vengosh A (2013) Geochemical and isotopic variations in shallow groundwater in areas of the Fayetteville shale development, north-central Arkansas. App Geochem. doi:10.​1016/​j.​apgeochem.​2013.​04.​013
Wopfner H (1972) Depositional history and tectonics of South Australia sedimentary basins. Mineral Resources Review, 133. Department of Mines, South Australia, Adelaide, Australia, pp 32–50
Wopfner H, Freytag B, Heath GR (1970) Basal Jurassic-Cretaceous rocks of the Western Great Artesian Basin, South Australia: stratigraphy and environment. Am Assoc Petrol Geol Bull 54(3):383–416
Metadaten
Titel
Analysis of subsurface mound spring connectivity in shale of the western margin of the Great Artesian Basin, South Australia
verfasst von
Todd Halihan
Andrew Love
Mark Keppel
Volmer Berens
Publikationsdatum
01.11.2013
Verlag
Springer Berlin Heidelberg
Erschienen in
Hydrogeology Journal / Ausgabe 7/2013
Print ISSN: 1431-2174
Elektronische ISSN: 1435-0157
DOI
https://doi.org/10.1007/s10040-013-1034-8

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