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Hydrogeology Journal

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01-11-2008 | Report

Surface water–groundwater interaction and chemistry in a mineral-armored hydrothermal outflow channel, Yellowstone National Park, USA

Authors: M. V. Vitale, P. Gardner, N. W. Hinman

Published in: Hydrogeology Journal | Issue 7/2008

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Abstract

Small quantities of groundwater interact with hydrothermal surface water to drive in-stream geochemical processes in a silica-armored hot-spring outflow channel in Yellowstone National Park, USA. The objective of this study was to characterize the hydrology and geochemistry of this unique system in order to (1) learn more about the Yellowstone Plateau’s subsurface water mixing between meteoric and hydrothermal waters and (2) learn more about the chemical and physical processes that lead to accumulation of streambed cements, i.e., streambed armor. A combination of hydrological, geochemical, mineralogical, microscopic, and petrographic techniques were used to identify groundwater and surface-water exchange. Interaction could be identified in winter because of differences in surface water and groundwater composition but interaction at other times of the year cannot be ruled out. Dissolved constituents originating from groundwater (e.g., Fe(II) and Mg) were traced downstream until oxidation and/or subsequent precipitation with silica removed them, particularly where high affinity substrates like cyanobacterial surfaces were present. Because the stream lies in a relatively flat drainage basin and is fed mainly by a seasonally relatively stable hot spring, this system allowed study of the chemical processes along a stream without the obscuring effects of sedimentation.

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Herein, the term, unconfined groundwater system, is defined as one in which the surface pressure is dictated by atmospheric pressure, the upper surface is the water table, and recharge is usually through direct atmospheric precipitation or from surface water. The term, confined groundwater system, is defined as one in which the pressure is not dictated by atmospheric pressure, the piezometric surface is not the water table but rather is above the water table, and discharge is often from springs such as the hot springs in Yellowstone.

Although ice was observed in the tops of all piezometers during winter, the water in piezometers was sampled after purging the well and ensuring that pH and temperature had stabilized; the water sampled is representative of the groundwater and not simply the water sitting in the piezometers when sampling began.

Other elements would be expected to come from groundwater as well but the reported 10% error in analytical methods (ICP and IC) exceeded the projected contribution; iron concentrations were determined using the more specific Ferrozine method.

Aramaki Y, Yokoyama T, Okaue Y, Watanabe K (2004) Chemical adsorption of silicic acid to aluminum combined with cation exchange and chelate resins as model compounds of the surface of microbes. Chem Geol 212:339–349CrossRef

Christiansen RL (2001) The Quaternary and Pliocene Yellowstone Plateau volcanic field of Wyoming, Idaho, and Montana, US Geological Survey, Denver, CO

Cox ER (1973) Water resources of Yellowstone National Park, Wyoming, Montana, and Idaho, US Geological Survey, Denver, CO

DeMonge JM (1999) Streambed armoring in Iron Spring Creek, Yellowstone National Park, Wyoming: ground water-surface water interactions. MSc Thesis, University of Montana, USA

DeMonge JM, Hinman NW, Woessner WW (1998) Groundwater–surface water interaction in thermal areas: streambed armoring and its affect on stream water chemistry. In: AGU Fall Meeting, San Francisco, CA, December 1998

Ehrlich R, Crabtree SJ, Horkowitz KO, Horkowitz JP (1991a) Petrography and reservoir physics: I, objective classification of reservoir porosity. AAPG Bull 75:1547–1562

Ehrlich R, Etris EL, Brumfield D, Yuan LP, Crabtree SJ (1991b) Petrography and reservoir physics: III, physical models for permeability and formation factor. AAPG Bull 75:1579–1592

Fournier RO (1989) Geochemistry and dynamics of the Yellowstone National Park hydrothermal system. Annu Rev Earth Planet Sci 17:13–53CrossRef

Friedman I, Lipman PW, Obradovich JD, Gleason JD (1974) Meteoric water in magmas. Science 184:1069–1072CrossRef

Gibson M (1999) Hydrothermal water/groundwater interaction: a comparative study of electromagnetic terrain-conductivity mapping and standard hydrogeochemical techniques. MSc Thesis, University of Montana, USA

Gibson ML, Hinman NW (1997) Electromagnetic conductivity mapping of zones of geochemical interaction between local groundwater and alkaline hot spring discharge. EOS Trans Am Geophys Union 78:808. http://lib4.wsulibs.wsu.edu:808/rmwp. Cited July 2008

Gudmundsson SR, Einarsson E (1989) Controlled silica precipitation in geothermal brine at the Reykjanes Geo-chemicals Plant. Geothermics 18:105–112CrossRef

Harris R (1967) Silica and chloride in interstitial waters of river and lake sediments. Limnol Oceanogr 12:8–12CrossRef

Hinman NW (1998) Sequences of silica phase transitions: effects of Na, Mg, K, Al and Fe ions. Mar Geol 147:13–24CrossRef

Hoehn E, Von Gunten HR (1989) Radon in groundwater: a tool to assess infiltration from surface waters to aquifers. Water Resour Res 25:1795–1803CrossRef

Iler RK (1973) Effect of adsorbed alumina on the solubility of amorphous silica in water. J Colloid Interface Sci 43:399–408CrossRef

Iler RK (1979) The chemistry of silica. Wiley, New York

Ingebritsen S, Galloway DL, Colvard EM, Sorey ML, Mariner RH (2001) Time-variation of hydrothermal discharge at selected sites in the western United States: implications for monitoring. Volcanol Geotherm Res 111:1–23CrossRef

Johnson SY, Stephenson WJ, Morgan LA, Shanks WCI, Pierce KL (2003) Hydrothermal and tectonic activity in northern Yellowstone Lake, Wyoming. Geol Soc Am Bull 115:954–971CrossRef

Keith T, Muffler L (1978) Minerals produced during cooling and hydrothermal alteration of ash flow tuff from Yellowstone Drill Hole Y-5. J Volcanol Geotherm Res 3:373–402CrossRef

Kendall TA (1999) Early diagenesis of thermal spring deposits. MSc Thesis, University of Montana, Missoula, USA

Kendall TA, Hinman NW (1998) Early diagenesis of thermal spring deposits. In: Abstract, AGU Fall Meeting, San Francisco, CA, December 1998, p 1

Kharaka YK, Sorey ML, Thordsen JJ (2000) Large-scale hydrothermal fluid discharges in the Norris-Mammoth corridor, Yellowstone National Park, USA. J Geochem Explor 69:201–205CrossRef

Kharaka YK, Thordsen JJ, White LD (2002) Isotope and chemical compositions of meteoric and thermal waters and snow from the greater Yellowstone National Park region. US Geol Surv 2002–194. http://pubs.usgs.gov/of/2002/ofr02-194/

Lister C (1980) Heat flow and hydrothermal circulation. Annu Rev Earth Planet Sci 8:95–117CrossRef

McKenzie D, Nimmo F (1999) The generation of Martian floods by the melting of ground ice above dykes. Nature 397:231–233CrossRef

Mowers T, Budd D (1996) Quantification of porosity and permeability reduction due to calcite cementation using computer-assisted petrographic image analysis techniques. AAPG Bull 80:309–322

Parkhurst DL, Appelo CAJ (1999) User’s guide to PHREEQC (version 2): a computer program for speciation, batch-reaction, one-dimensional transport, and inverse geochemical calculations. US Geological Survey, Reston, VA

Rye RO, Truesdell AH (1993) The question of recharge to the geysers and hot springs of Yellowstone National Park. US Geological Survey, Reston, VA, pp 93–384

Sorey ML (ed) (1991) Effects of potential geothermal development in the Corwin Springs known geothermal resources area, Montana, on the thermal features of Yellowstone National Park. US Geological Survey, Menlo Park, CA

White DE, Fournier RO, Muffler LJP, Truesdell AH (1975) Physical results of research drilling in thermal areas of Yellowstone National Park, Wyoming. US Government Printing Office, Washington, DC

Yee N, Phoenix VR, Konhauser KO, Benning LG, Harris FG (2003) The effect of cyanobacteria on silica precipitation at neutral pH: implications for bacterial silicification in geothermal hot springs. Chem Geol 199:83–90CrossRef

Yokoyama T, Takahashi Y, Yamanaka C, Tarutani T (1989) Effect of aluminum on the polymerization of silicic acid in aqueous solution and the deposition of silica. Geothermics 18:321–325CrossRef

Yokoyama T, Taguchi S, Motomura Y, Watanabe K, Nakanishi T, Aramaki Y, Izawa E (2004) The effect of aluminum on the biodeposition of silica in hot spring water: chemical state of aluminum in siliceous deposits collected along the hot spring water stream of Steep Cone hot spring in Yellowstone National Park, USA. Chem Geol 212:329–337CrossRef

Zablocki C, Tilling R, Peterson D, Christiansen R, Keller G, Murray J (1974) A deep research drill hole at the summit of an active volcano, Kilauea, Hawaii. Geophys Res Lett 1:323–326CrossRef

Title: Surface water–groundwater interaction and chemistry in a mineral-armored hydrothermal outflow channel, Yellowstone National Park, USA
Authors: M. V. Vitale
P. Gardner
N. W. Hinman
Publication date: 01-11-2008
Publisher: Springer-Verlag
Published in: Hydrogeology Journal / Issue 7/2008
Print ISSN: 1431-2174
Electronic ISSN: 1435-0157
DOI: https://doi.org/10.1007/s10040-008-0344-8

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