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Environmental Earth Sciences
Erschienen in: Environmental Earth Sciences 6/2012

01.11.2012 | Original Article

Using geochemistry to identify the source of groundwater to Montezuma Well, a natural spring in Central Arizona, USA: part 2

verfasst von: Raymond H. Johnson, Ed. DeWitt, Laurie Wirt, Andrew H. Manning, Andrew G. Hunt

Erschienen in: Environmental Earth Sciences | Ausgabe 6/2012

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Abstract

Montezuma Well is a unique natural spring located in a sinkhole surrounded by travertine. Montezuma Well is managed by the National Park Service, and groundwater development in the area is a potential threat to the water source for Montezuma Well. This research was undertaken to better understand the sources of groundwater to Montezuma Well. Strontium isotopes (87Sr/86Sr) indicate that groundwater in the recharge area has flowed through surficial basalts with subsequent contact with the underlying Permian aged sandstones and the deeper, karstic, Mississippian Redwall Limestone. The distinctive geochemistry in Montezuma Well and nearby Soda Springs (higher concentrations of alkalinity, As, B, Cl, and Li) is coincident with added carbon dioxide and mantle-sourced He. The geochemistry and isotopic data from Montezuma Well and Soda Springs allow for the separation of groundwater samples into four categories: (1) upgradient, (2) deep groundwater with carbon dioxide, (3) shallow Verde Formation, and (4) mixing zone. δ18O and δD values, along with noble gas recharge elevation data, indicate that the higher elevation areas to the north and east of Montezuma Well are the groundwater recharge zones for Montezuma Well and most of the groundwater in this portion of the Verde Valley. Adjusted groundwater age dating using likely 14C and δ13C sources indicate an age for Montezuma Well and Soda Springs groundwaters at 5,400–13,300 years, while shallow groundwater in the Verde Formation appears to be older (18,900). Based on water chemistry and isotopic evidence, groundwater flow to Montezuma Well is consistent with a hydrogeologic framework that indicates groundwater flow by (1) recharge in higher elevation basalts to the north and east of Montezuma Well, (2) movement through the upgradient Permian and Mississippian units, especially the Redwall Limestone, and (3) contact with a basalt dike/fracture system that provides a mechanism for groundwater to flow to the surface. While the exact nature of the groundwater flow connections is still uncertain, the available data indicate that flow to Montezuma Well may be more susceptible to future groundwater development in the Redwall Limestone than from any other geologic unit. Overall, the shallow groundwater in the surrounding Verde Formation appears to be largely disconnected from deeper groundwater flowing to Montezuma Well.
Vorheriger Artikel Using hydrogeology to identify the source of groundwater to Montezuma Well, a natural spring in Central Arizona, USA: part 1
Nächster Artikel Reviews on books and media

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Literatur
Aeschbach-Hertig W, Peeters F, Beyerle U, Kipfer R (1999) Interpretation of dissolved atmospheric noble gases in natural waters. Water Resour Res 35:2779–2792CrossRef
Aeschbach-Hertig W, Peeters F, Beyerle U, Kipfer R (2000) Paleotemperature reconstruction from noble gases in ground water taking into account equilibration with entrapped air. Nature 405:1040–1043CrossRef
Appelo CAJ, Postma D (2005) Geochemistry. Groundwater and Pollution, 2nd edn. AA Balkema, Leiden, p 649CrossRef
Arizona Department of Water Resources (2000) Verde River Watershed Study. Arizona Department of Water Resources report, 208 p plus appendices
Ballentine CJ, Burnard PG (2002) Production, release, and transport of noble gases in the continental crust. In: Porcelli D, Ballentine CJ, Wieler R (eds) Reviews in mineralogy and geochemistry, vol 47., Noble gases in geochemistry and cosmochemistryMineralogical Society of America, Washington, D.C., pp 481–538
Ballentine CJ, Hall CM (1999) Determining paleotemperature and other variables by using an error-weighted, nonlinear inversion of noble gas concentrations in water. Geochim Cosmochim Acta 63:2315–2336CrossRef
Ballentine CJ, Burgess R, Marty B (2002) Tracing fluid origin, transport and interaction in the crust. In: Porcelli D, Ballentine CJ, Wieler R (eds) Reviews in mineralogy and geochemistry, vol 47., Noble gases in geochemistry and cosmochemistryMineralogical Society of America, Washington, D.C., pp 539–614
Blasch KW, Bryson JR (2007) Distinguishing sources of groundwater recharge by using δ2H and δ18O. Groundwater 45(3):294–308CrossRef
Blasch KW, Hoffmann JP, Graser LF, Bryson JR, Flint AL (2006) Hydrogeology of the upper and middle Verde River watersheds, central Arizona. US Geological Survey Scientific Investigations Report 2005-5198, 101 p, 3 plates
Clark ID, Fritz P (1997) Environmental isotopes in hydrogeology. Lewis Publishers, New York, p 328
Clarke WB, Jenkins WB, Top Z (1976) Determination of tritium by mass spectrometric measurements of 3He. Int J Appl Radiat Is 27:217–225CrossRef
Craig H, Lupton JE, Welhan JA, Poreda RJ (1978) Helium isotopic ratios in Yellowstone and Lassen Park volcanic gases. Geophys Res Lett 5:897–900CrossRef
Crossey LJ, Fischer TB, 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 34:25–28CrossRef
Crossey LJ, Karlstrom KE, Springer AE, Newell D, Hilton DR, Fischer T (2009) Degassing of mantle-derived CO2 and He from springs in the southern Colorado Plateau region—Neotectonic connections and implications for groundwater systems. Geol Soc Am Bull 121:7–8
Domenico PA, Schwartz FA (1990) Physical and chemical hydrogeology. Wiley, New York 824
Hancock PL, Chalmers RML, Altunel E, Cakir Z (1999) Travitonics: using travertine in active fault studies. J Struc Geo 21:903–916CrossRef
Heaton THE, Vogel JC (1981) ‘Excess air’ in groundwater. J Hydrol 50:201–216CrossRef
Johnson RH, DeWitt E, Wirt L, Arnold LR, Horton JD (2011) Water and rock geochemistry, geologic cross sections, geochemical modeling, and groundwater flow modeling for identifying the source of groundwater to Montezuma Well, a national spring in Central Arizona. US Geological Survey Open-File Report 2011-1063, 62 p
Johnson RH, DeWitt E, Arnold RL (2012) Using hydrogeology to identify the source of groundwater to Montezuma Well, a natural spring in Central Arizona, USA (part1). Environ Earth Sci. doi:10.​1007/​s12665-012-1801-1
Kennedy BM, Kharaka YK, Evans WC, Ellwood A, DePaolo DJ, Thordsen J, Ambats G, Mariner RH (1997) Mantle fluids in the San Andreas fault system, California. Science 278:1278–1281CrossRef
Kipfer R, Aeschbach-Hertig W, Peeters F, Stute M (2002) Noble gases in lakes and ground waters. In: Porcelli D, Ballentine CJ, Wieler R (eds) Reviews in mineralogy and geochemistry, vol 47., Noble gases in geochemistry and cosmochemistry. Mineralogical Society of America, Washington, D.C., pp 615–700
Konieczki AD, Leake SA (1997) Hydrogeology and water chemistry of Montezuma Well in Montezuma Castle National Monument and surrounding area, Arizona. US Geological Survey Water Resources Investigations Report WRI 97-4156, 49 p
Lange A (1957) Studies on the origin of Montezuma Well and Cave, Arizona, Publication of the Western Speleological Institute, Inc. Cave Studies 1:9 (Manuscript in the files of the University of Arizona Special Collections)
Lee JY, Hahn JS (2006) Characterization of groundwater temperature obtained from the Korean national groundwater monitoring stations: Implications for heat pumps. J Hydrol 329:514–526CrossRef
Manning AH (2009) Ground-water temperature, noble gas, and carbon isotope data from the Española Basin, New Mexico. US Geological Survey Scientific Investigations Report 2008-5200, 69 p
Manning AH, Solomon DK (2003) Using noble gases to investigate mountain-front recharge. J Hydrol 275:194–207CrossRef
Matsuo S, Suzuki M, Mizutani Y (1978) Nitrogen to argon ratios in volcanic gases. In: Alexander EC Jr, Ozima M (eds) Terrestrial rare gases. Tokyo Center for Academic Publications, Japan, pp 17–25
McKee ED, Hastings H, Colton HS (1947) Montezuma’s Well, result of preliminary soundings, July 18, 1947 (Manuscript in files of Museum of Northern Arizona)
Newell DL, Crossey LJ, Karlstrom KE, Fischer TP (2005) Continental-scale links between the mantle and groundwater systems of the western United States: evidence from travertine springs and regional He isotope data. Geol Soc Am Today 15(12):4–10
Owen-Joyce SJ, Bell CK (1983) Appraisal of water resources in the upper Verde River area, Yavapai and Coconino Counties, Arizona. Arizona Department of Water Resources Bulletin 2, 219 p
Solomon DK (2000) 4He in groundwater. In: Cook PG, Herczeg AL (eds) Environmental tracers in subsurface hydrology. Kluwer, Boston, pp 425–439
Stute M, Schlosser P (2000) Atmospheric noble gases. In: Cook PG, Herczeg AL (eds) Environmental tracers in subsurface hydrology. Kluwer, Boston, pp 349–377
Symonds RB, Poreda RJ, Evans WC, Janik CJ, Ritchie BE (2003) Mantle and crustal sources of carbon, nitrogen, and noble gases in Cascade-Range and Aleutian-Arc volcanic gases. US Geological Survey Open-File Report 03-436
Twenter FR, Metzger DG (1963) Geology and groundwater in Verde Valley—the Mogollon Rim region Arizona. US Geological Survey Bulletin 1177, 132 p
Wirt L, DeWitt E (2005) Geochemistry of major aquifers and springs. In: Wirt L, DeWitt E, Langenheim VE (eds) Geologic framework of aquifer units and ground-water flowpaths in the Verde River Headwaters, north-central Arizona. US Geological Survey Open-File Report 2004-1411
Zuber A, Weise SM, Osenbruck K, Grabczak J, Ciezkowski W (1995) Age and recharge area of thermal waters in Ladek Spa (Sudeten, Poland) deduced from environmental isotope and noble gas data. J Hydrol 167:327–349CrossRef
Metadaten
Titel
Using geochemistry to identify the source of groundwater to Montezuma Well, a natural spring in Central Arizona, USA: part 2
verfasst von
Raymond H. Johnson
Ed. DeWitt
Laurie Wirt
Andrew H. Manning
Andrew G. Hunt
Publikationsdatum
01.11.2012
Verlag
Springer-Verlag
Erschienen in
Environmental Earth Sciences / Ausgabe 6/2012
Print ISSN: 1866-6280
Elektronische ISSN: 1866-6299
DOI
https://doi.org/10.1007/s12665-012-1844-3

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