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Hydrogeology Journal

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03-07-2017 | Report

Chemical evolution of groundwater in the Wilcox aquifer of the northern Gulf Coastal Plain, USA

Authors: Estifanos Haile, Alan E. Fryar

Published in: Hydrogeology Journal | Issue 8/2017

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Abstract

The Wilcox aquifer is a major groundwater resource in the northern Gulf Coastal Plain (lower Mississippi Valley) of the USA, yet the processes controlling water chemistry in this clastic aquifer have received relatively little attention. The current study combines analyses of solutes and stable isotopes in groundwater, petrography of core samples, and geochemical modeling to identify plausible reactions along a regional flow path ∼300 km long. The hydrochemical facies evolves from Ca-HCO₃ upgradient to Na-HCO₃ downgradient, with a sequential zonation of terminal electron-accepting processes from Fe(III) reduction through SO₄ ²⁻ reduction to methanogenesis. In particular, decreasing SO₄ ²⁻ and increasing δ³⁴S of SO₄ ²⁻ along the flow path, as well as observations of authigenic pyrite in core samples, provide evidence of SO₄ ²⁻ reduction. Values of δ¹³C in groundwater suggest that dissolved inorganic carbon is contributed both by oxidation of sedimentary organic matter and calcite dissolution. Inverse modeling identified multiple plausible sets of reactions between sampled wells, which typically involved cation exchange, pyrite precipitation, CH₂O oxidation, and dissolution of amorphous Fe(OH)₃, calcite, or siderite. These reactions are consistent with processes identified in previous studies of Atlantic Coastal Plain aquifers. Contrasts in groundwater chemistry between the Wilcox and the underlying McNairy and overlying Claiborne aquifers indicate that confining units are relatively effective in limiting cross-formational flow, but localized cross-formational mixing could occur via fault zones. Consequently, increased pumping in the vicinity of fault zones could facilitate upward movement of saline water into the Wilcox.

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Arthur JK, Taylor RE (1986) Mississippi embayment aquifer system in Mississippi: geohydrologic data compilation for flow model simulation. Water Resour Bull 22:1021–1029CrossRef

Bense VF, Person MA (2006) Faults as conduit-barrier systems to fluid flow in siliciclastic sedimentary aquifers. Water Resour Res 42:W05421. doi:10.1029/2005WR004480 CrossRef

Böttcher J, Strebel O, Voerkelius S, Schmidt HL (1990) Using isotope fractionation of nitrate-nitrogen and nitrate-oxygen for evaluation of microbial denitrification in a sandy aquifer. J Hydrol 114:413–424CrossRef

Brahana JV, Mesko TO(1988) Hydrogeology and preliminary assessment of regional flow in the Upper Cretaceous and adjacent aquifers in the northern Mississippi embayment. US Geol Surv Water Resour Invest Rep 87-4000, 65 pp

Brahana JV, Mesko TO, Busby JF, Kraemer TF (1985) Ground-water quality data from the northern Mississippi embayment: Arkansas, Missouri, Kentucky, Tennessee, and Mississippi. US Geol Surv Open-File Rep 85-683, 15 pp

Carmody RW, Plummer LN, Busenberg E, Coplen TB (1998) Methods for collection of dissolved sulfate and sulfide and analysis of their sulfur isotopic composition. US Geol Surv Open-File Rep 97-234, 91 pp

Cederstrom DJ (1946) Genesis of ground waters in the coastal plain of Virginia. Econ Geol 41:218–245CrossRef

Chapelle FH (1993) Ground-water microbiology and geochemistry. Wiley, Chichester, UK

Chapelle FH, Knobel LL (1985) Stable carbon isotopes of DIC in the Aquia aquifer, Maryland: evidence for an isotopically heavy source of CO₂. Ground Water 23:592–599CrossRef

Chapelle FH, Lovley DR (1992) Competitive exclusion of sulfate reduction by Fe(III)-reducing bacteria: a mechanism for producing discrete zones of high-iron ground water. Ground Water 30:29–36CrossRef

Chapelle FH, McMahon PB (1991) Geochemistry of dissolved inorganic carbon in a coastal plain aquifer: 1. sulfate from confining beds as an oxidant in microbial CO₂ production. J Hydrol 127:85–108CrossRef

Chapelle FH, Zelibor JL, Grimes DJ, Knobel LL (1987) Bacteria in deep coastal plain sediments of Maryland: a possible source of CO₂ to groundwater. Water Resour Res 23:1625–1632CrossRef

Chapelle FH, Bradley PM, Thomas MA, McMahon PB (2009) Distinguishing iron-reducing from sulfate-reducing conditions. Ground Water 47:300–305CrossRef

CHEMetrics (2017) Test kits. CHEMetrics, Midland, VA. https://www.chemetrics.com/index.php?route=product/category&path=59. Accessed 13 March 2017

Clark BR, Hart RM (2009) The Mississippi embayment regional aquifer study (MERAS): documentation of a groundwater-flow model constructed to assess water availability in the Mississippi Embayment. US Geol Surv Sci Invest Rep 2009-5172, 61 pp

Clarke JS, Hacke CM, Peck MF (1990) Geology and ground-water resources of the coastal area of Georgia. Georgia Geol Surv Bull 113:106

Clark BR, Hart RM, Gurdak JJ (2011) Groundwater availability of the Mississippi embayment. US Geol Surv Prof Pap 1785:62

Drever JI (1997) The geochemistry of natural waters, 3rd edn. Prentice Hall, Englewood Cliffs, NJ

Fogg GE, Kreitler CW (1982) Ground-water hydraulics and hydrochemical facies in Eocene aquifers of the east Texas basin. Bur Econ Geol Univ Tex Austin Rep Inv 127:75

Foster MD (1950) The origin of high sodium bicarbonate waters in the Atlantic and Gulf Coastal Plains. Geochim Cosmochim Acta 1:33–48CrossRef

Hach (2017) Manual titrators. Hach, Loveland, CO. https://www.hach.com/titration-systems/manual-titrators/family?productCategoryId=35547627760. Accessed 13 March 2017

Haile E (2011) Chemical evolution and residence time of groundwater in the Wilcox aquifer of the northern Gulf Coastal Plain. PhD Thesis, University of Kentucky, Lexington, KY, USA. http://uknowledge.uky.edu/ees_etds/2/. Accessed 3 October 2016

Hart RM, Clark BR, Bolyard SE (2008) Digital surfaces and thicknesses of selected hydrogeologic units within the Mississippi embayment regional aquifer study (MERAS). US Geol Surv Sci Invest Rep 2008-5098, 33 pp

Hosman RL (1996) Regional stratigraphy and subsurface geology of Cenozoic deposits, Gulf coastal plain, south-central United States. US Geol Surv Prof Pap 1416-G:35

Hosman RL, Long AT, Lambert TW, Jeffery HG (1968) Water resources of the Mississippi embayment: Tertiary aquifers in the Mississippi embayment, with discussions of quality of the water. US Geol Surv Prof Pap 448-D:29

Johnston AC, Schweig ES (1996) The enigma of the New Madrid earthquakes of 1811–1812. Annu Rev Earth Planet Sci 24:339–384CrossRef

Katz BG, Kingsbury JA, Welch HL, Tollett RW (2012) Processes affecting geochemistry and contaminant movement in the middle Claiborne aquifer of the Mississippi embayment aquifer system. Environ Earth Sci 65:1759–1780CrossRef

Kennedy CD, Genereux DP (2007) ¹⁴C groundwater age and the importance of chemical fluxes across aquifer boundaries in confined Cretaceous aquifers of North Carolina, USA. Radiocarbon 49:1181–1203CrossRef

Kingsbury JA, Parks WS (1993) Hydrogeology of the principal aquifers and relation of faults to interaquifer leakage in the Memphis area, Tennessee. US Geol Surv Water Resour Invest Rep 93-4075, 18 pp

Kresse TM, Clark BR (2008) Occurrence, distribution, sources, and trends of elevated chloride concentrations in the Mississippi River Valley alluvial aquifer in southeastern Arkansas. US Geol Surv Sci Invest Rep 2008-5193, 34 pp

Lee RW (1985) Geochemistry of groundwater in Cretaceous sediments of the southeastern coastal plain of eastern Mississippi and western Alabama. Water Resour Res 21:1545–1556CrossRef

Lee RW, Strickland DJ (1988) Geochemistry of groundwater in Tertiary and Cretaceous sediments of the southeastern coastal plain in eastern Georgia, South Carolina, and southeastern North Carolina. Water Resour Res 24:291–303CrossRef

Lee MK, Griffin J, Saunders J, Wang Y, Jean JS (2007) Reactive transport of trace elements and isotopes in the Eutaw coastal plain aquifer, Alabama. J Geophys Res 112:G02026

Lovley DR, Klug MJ (1986) Model for the distribution of sulfate reduction and methanogenesis in freshwater sediments. Geochim Cosmochim Acta 50:11–18CrossRef

McIntosh JC, Warwick PD, Martini AM, Osborn SG (2010) Coupled hydrology and biogeochemistry of Paleocene-Eocene coal beds, northern Gulf of Mexico. GSA Bull 122:1248–1264CrossRef

McMahon PB, Chapelle FH (1991a) Geochemistry of dissolved inorganic carbon in a coastal plain aquifer: 2. modeling carbon sources, sinks, and δ¹³C evolution. J Hydrol 127:109–135CrossRef

McMahon PB, Chapelle FH (1991b) Microbial production of organic acids in aquitard sediments and its role in aquifer geochemistry. Nature 349:233–235CrossRef

Mukherjee A, Fryar AE (2008) Deeper groundwater chemistry and geochemical modeling of the arsenic affected western Bengal basin, West Bengal, India. Appl Geochem 23:863–894CrossRef

Nicot J-P, Larson T, Darvari R, Mickler P, Slotten M, Aldridge J, Uhlman K, Costley R (2017) Controls on methane occurrences in shallow aquifers overlying the Haynesville Shale gas field, east Texas. Groundwater. doi:10.1011/gwat.12500, 12 pp

Oman JK (1986) Stratigraphic framework and correlation of the Tertiary lignite-bearing formations from southeast Missouri to the fort pillow test well of west Tennessee. US Geol Surv Bull 1644:7

Park J, Sanford RA, Bethke CM (2006) Geochemical and microbiological zonation of the Middendorf aquifer, South Carolina. Chem Geol 230:88–104CrossRef

Parkhurst DL, Appelo CAJ (2013) Description of input and examples for PHREEQC version 3: a computer program for speciation, batch-reaction, one-dimensional transport, and inverse geochemical calculations. US Geol Surv Techniques Methods 6–A43:497

Parkhurst DL, Christenson S, Breit GN (1996) Ground-water-quality assessment of the central Oklahoma aquifer, Oklahoma: geochemical and geohydrologic investigations. US Geol Surv Water Suppl Pap 2357-C:101

Paul JM, Larsen D (2014) Determining the source of saline groundwater from the Mississippi River Valley alluvial aquifer in southeast Arkansas. Geol Soc Am Abstr Prog 46(1):8. https://gsa.confex.com/gsa/2014SC/webprogram/Paper235627.html. Accessed 3 October 2016

Penny E, Lee MK, Morton C (2003) Groundwater and microbial processes of Alabama coastal plain aquifers. Water Resour Res 39:1320. doi:10.1029/2003WR001963 CrossRef

Pettijohn RA (1996) Geochemistry of ground water in the Gulf Coast aquifer systems, south-central United States. US Geol Surv Water Resour Invest Rep 96-4107, 158 pp

Piper AM (1944) A graphic procedure in the geochemical interpretation of water analyses. Trans Am Geophys Union 25:914–923CrossRef

Plummer LN, Busby JF, Lee RW, Hanshaw BB (1990) Geochemical modeling of the Madison aquifer in parts of Montana, Wyoming, and South Dakota. Water Resour Res 26:1981–2014CrossRef

Pucci AA, Owens JP (1989) Geochemical variations in a core of hydrogeologic units near Freehold, New Jersey. Ground Water 27:802–812CrossRef

Pugh AL (2010) Potentiometric surfaces and water-level trends in the Cockfield (upper Claiborne) and Wilcox (lower Wilcox) aquifers of southern and northeastern Arkansas, 2009. US Geol Surv Sci Invest Rep 2010–5014, 47 pp

Schrader TP (2007) Potentiometric surfaces and water-level trends in the Cockfield and Wilcox aquifers of southern and northeastern Arkansas, 2006. US Geol Surv Sci Invest Rep 2007-5218, 28 pp

Schwartz FW, Zhang H (2003) Fundamentals of ground water. Wiley, Chichester, UK

Steefel CI, Van Cappellen P (1990) A new kinetic approach to modeling water–rock interaction: the role of nucleation, precursors, and Ostwald ripening. Geochim Cosmochim Acta 54:2657–2677CrossRef

Tardy Y (1971) Characterization of the principal weathering types by the geochemistry of waters from some European and African crystalline massifs. Chem Geol 7:253–271CrossRef

US Climate Data (2016) Climate – United States – monthly averages. http://www.usclimatedata.com/. Accessed 3 October 2016

US Geological Survey (2016a) Alkalinity calculator. http://or.water.usgs.gov/alk/. Accessed 3 October 2016

US Geological Survey (2016b) USGS water data for the nation. http://waterdata.usgs.gov/nwis. Accessed 3 October 2016

Warwick PD, Breland FC, Hackley PC (2008) Biogenic origin of coalbed gas in the northern Gulf of Mexico coastal plain, USA. Int J Coal Geol 76:119–137CrossRef

Williamson AK, Grubb HF (2001) Ground-water flow in the Gulf Coast aquifer systems, south-central United States. US Geol Surv Prof Pap 1416-F:173

Wolf LW, Lee MK, Browning S, Tuttle MP (2005) Numerical analysis of overpressure development in the New Madrid seismic zone. Bull Seismol Soc Am 95:135–144CrossRef

Wood WW (1981) Guidelines for collection and field analysis of ground-water samples for selected unstable constituents. US Geol Surv Techniques Water Resour Invest 01-D2, 24 pp

Woolery EW, Wang Z, Carpenter NS, Street R, Brengman C (2016) The Central United States Seismic observatory: site characterization, instrumentation, and recordings. Seismol Res Lett 87:215–228CrossRef

Yeatts DS (2004) Potentiometric surfaces in the Cockfield and Wilcox aquifers of southern and northeastern Arkansas, 2003. US Geol Surv Sci Invest Rep 2004-5169, 29 pp

Zhang C, Grossman EL, Ammerman JW (1998) Factors influencing methane distribution in Texas ground water. Ground Water 36:58–66CrossRef

Zhu C (2005) In situ feldspar dissolution rates in an aquifer. Geochim Cosmochim Acta 69:1435–1453CrossRef

ZoBell CE (1946) Studies on redox potential of marine sediments. AAPG Bull 30:477–513

Title: Chemical evolution of groundwater in the Wilcox aquifer of the northern Gulf Coastal Plain, USA
Authors: Estifanos Haile
Alan E. Fryar
Publication date: 03-07-2017
Publisher: Springer Berlin Heidelberg
Published in: Hydrogeology Journal / Issue 8/2017
Print ISSN: 1431-2174
Electronic ISSN: 1435-0157
DOI: https://doi.org/10.1007/s10040-017-1608-y

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