Hostname: page-component-cd9895bd7-gxg78 Total loading time: 0 Render date: 2024-12-24T00:15:23.608Z Has data issue: false hasContentIssue false

Paleo-climate of the Boise area, Idaho from the last glacial maximum to the present based on groundwater δ2H and δ18O compositions

Published online by Cambridge University Press:  20 January 2017

Melissa E. Schlegel
Affiliation:
Department of Geosciences, Brigham Young University, Provo, UT 84602, USA
Alan L. Mayo*
Affiliation:
Department of Geosciences, Brigham Young University, Provo, UT 84602, USA
Steve Nelson
Affiliation:
Department of Geosciences, Brigham Young University, Provo, UT 84602, USA
Dave Tingey
Affiliation:
Department of Geosciences, Brigham Young University, Provo, UT 84602, USA
Rachel Henderson
Affiliation:
Department of Geosciences, Brigham Young University, Provo, UT 84602, USA
Dennis Eggett
Affiliation:
Department of Statistics, Brigham Young University, Provo, UT 84602, USA
*
Corresponding author. Email Address:[email protected]

Abstract

A 30 ka paleo-climate record of the Boise area, Idaho, USA has been delineated using groundwater stable isotopic compositions. Groundwater ages are modern (cold batholith), 5–15 ka (thermal batholith), 10–20 ka (frontal fault), and 20–30 ka (Snake River plain thermal). The stable isotopic composition of groundwaters have been used as a surrogate for the stable isotopic composition of precipitation. Using δ2H and δ18O compositions, local groundwater lines (LGWL's) were defined for each system. Each LGWL has been evaluated with defined slopes of 6.94 and 8, respectively, and resulting deuterium excess values (d) were found for each groundwater system for each slope. Time dependent changes in moisture source humidity and temperature, and Boise area recharge temperatures, calculated from stable isotopic data and the deuterium excess factors, agree with previous paleo-climate studies. Results indicate that from the last glacial maximum to the present time the humidity over the ocean moisture source increased by 9%, sea surface temperature at the moisture source increased 6–7°C, and local Boise temperature increased by 4–5°C. A greater increase of temperature at the moisture source as compared to the Boise area may impart be due to a shift in the moisture source area.

Type
Articles
Copyright
University of Washington

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Barlow, L., White, J., Barry, R., Rogers, J., and Grootes, P. The North Atlantic oscillation signature in deuterium and deuterium excess signals in the Greenland ice sheet project 2 ice core, 1840–1970. Geophysical Research Letters 20, 24 (1993). 29012904.Google Scholar
Bennett, E.H. Relationship of the trans-Challis fault system in central Idaho to Eocene and basin and range extensions. Geology 14, 6 (1986). 481484.Google Scholar
Bradley, R.S. Paleoclimatology, Reconstructing Climates of the Quaternary. 2nd ed. (1999). Academic Press, Burlington, Massachusetts. 610 Google Scholar
Clark, I., and Fritz, P. Environmental Isotopes in Hydrology. (1997). Lewis Publishers, Boca Raton, Florida. 328 Google Scholar
COHMAP Members Climatic changes of the last 18,000 years: observations and model simulations. Science 241, (1988). 1,0431,052.Google Scholar
Craig, H. Isotopic variations in meteoric waters. Science 133, (1961). 17021703.Google Scholar
Craig, H., Grodon, L., and Horibe, Y. Isotopic exchange effects in the evaporation of water: low-temperature experimental results. Journal of Geophysical Research 68, 17 (1963). 50795087.CrossRefGoogle Scholar
Dansgaard, W. Stable isotopes in precipitation. Tellus 16, (1964). 436467.Google Scholar
Delmotte, M., Masson, V., Jouzel, J., and Morgan, V. A seasonal deuterium excess signal at Law Dome, coastal eastern Antarctica: a southern ocean signature. Journal of Geophysical Research 105, D6 (2000). 71877197.Google Scholar
Edmunds, W., and Wright, E. Groundwater recharge and paleoclimate in the Sirte and Kufra Basins, Libya. Journal of Hydrology 40, (1979). 215241.CrossRefGoogle Scholar
Fontes, J.C.h. Dating of groundwater in guidebook on nuclear techniques in hydrology: International Atomic Energy Agency. Technical Report Services 91, (1983). 285317.Google Scholar
Fontes, J.C.h., and Garnier, J.M. Determination of the initial 14C activity of the total dissolved carbon: a review of the existing models and a new approach. Water Resource Research 15, 2 (1979). 399413.Google Scholar
Gat, J., and Dansgaard, W. Stable isotope survey of fresh water occurrences in Israel and the Northern Jordan Rift Valley. Journal of Hydrology 16, (1972). 177212.Google Scholar
Gates, W.L. Modeling the ice-age climate: the July climate of 18,000 years ago has been simulated with a global atmospheric model. Science 191, (1976). 1,1381,344.CrossRefGoogle Scholar
Hendy, I.L., and Kennett, J.P. Latest Quaternary north Pacific surface-water responses imply atmosphere-driven climate instability. Geology 27, 4 (1999). 291294.Google Scholar
Hoffman, G., Jouzel, J., and Johnsen, S. Deuterium excess record from central Greenland over the last millennium: hints of a north Atlantic signal during the Little Ice Age. Journal of Geophysical Research 106, D13 (2001). 14,26514274.CrossRefGoogle Scholar
Holdaway, B., (1994). The geochemical evolution of cold and thermal ground waters in the southern part of the Idaho Batholith.: Master's Thesis, Brigham Young University, Provo., 73 p.Google Scholar
Hutchings, J., and Petrich, C.R. Groundwater recharge and flow in the regional Treasure Valley aquifer system: geochemistry and isotope study: Idaho Water Resources Research Institute. Research Report (2002). 91 IWRRI-2002–08 Google Scholar
IAEA/WMO, (2001). Global Network of Isotopes in Precipitation, The GNIP Database. Accessible at: http://isohis.iaea.org.Google Scholar
Jouzel, J., Merlivat, L., and Lorius, C. Deuterium excess in an East Antarctic ice core suggests higher relative humidity at the oceanic surface during the last glacial maximum. Nature 229, (1982). 688691.Google Scholar
Kaufman, D.S. Amino acid paleothermometry of Quaternary ostracodes from the Bonneville Basin, Utah. Quaternary Science Reviews 22, (2003). 899914.Google Scholar
Kirby, M.E., Mullens, H.T., Patterson, W.P., and Burnett, A.W. Late glacial-Holocene atmospheric circulation and precipitation in the northeast United States inferred from modern calibrated stable oxygen and carbon isotopes. Geological Society of America Bulletin 114, 10 (2002). 13261340.Google Scholar
Lewis, R., and Young, H. Thermal springs in the Boise River Basin, south-central Idaho. USGS Water-Resources Investigations 82–4006, (1982). 22 Google Scholar
Ludwig, K. ISOPLOT 3.00: a geochronological toolkit for EXCEL. Berkeley Geochronology Center Special Publication 4, (2003). 71 Google Scholar
Mayo, A., Muller, A., and Mitchell, J. Geochemical and isotopic investigations of thermal water occurrences of the Boise Front area, Ada County, Idaho. Idaho Department of Water Resources Water Information Bulletin 30, 14 (1984). 55 Google Scholar
Merlivat, L., and Jouzel, J. Global climatic interpretation of the deuterium-oxygen 18 relationship for precipitation. Journal of Geophysical Research 84, C8 (1979). 5,0295,033.Google Scholar
Muehlenbachs, K. Oxygen isotope exchange during weathering and low temperature alterations. Mineralogical Association of Canada. (1987). Special Publication, 162186.Google Scholar
Mink, L.L., Graham, D.L., (1977). Geothermal potential of the west Boise area.: Report RCSt-43–77: 37 p.Google Scholar
Mitchell, J., (1981). Geochemistry in Geological, hydrological, geochemical and geophysical investigations of the Nampa-Caldwell and adjacent areas. southwestern Idaho, Mitchell ed: Idaho Department of Water Resources Water Information Bulletin, n. 30, pt. 11, ch 4, 143 p.Google Scholar
Neary, M.P. Tritium enrichment: to enrich or not to enrich?. Radioactivity and Radiochemistry 8, 4 (1997). 2335.Google Scholar
Nelson, S.T. A simple, practical methodology for routine VSMOW/SLAP normalization of water sample analyzed by continuous flow methods. Rapid Communications in Mass Spectrometry 14, (2000). 10441046.Google Scholar
Nelson, S.T., and Dettman, D. Improving hydrogen isotope ratio measurements for on-line chromium reduction systems. Rapid Communications in Mass Spectrometry 15, (2001). 2,3012,306.Google Scholar
Nelson, S.T., Wood, M.J., Mayo, A.L., Tingey, D.G., and Eggett, D. Shoreline tufa and tufaglomerate from Pleistocene Lake Bonneville, Utah, USA: stable isotopic and mineralogical records of lake conditions, processes, and climate. Journal of Quaternary Science (2005). 117.Google Scholar
Petit, J., White, J., Young, N., Jouzel, J., and Korotkevich, Y. Deuterium excess in recent Antarctic snow. Journal of Geophysical Research 96, D3 (1991). 51135122.Google Scholar
Polach, H.A., and Stipp, J.J. Improved synthesis techniques for methane and benzene radiocarbon dating. International Journal of Applied Radiation and Isotopes 18, (1967). 359364.Google Scholar
Rademacher, L.K., Clark, J.F., and Hudson, G.B. Temporal changes in stable isotope compositon of spring waters: implications for recent changes in climate and atmospheric circulation. Geology 20, 2 (2002). 139142.Google Scholar
Rozanski, K. Deuterium and oxygen-18 in European groundwaters — links to atmospheric circulation in the past. Chemical Geology 52, (1985). 349363.Google Scholar
Stenni, B., Masson-Delmotte, V., Johnsen, S., Jouzel, J., Longinelli, A., Monnin, E., Rothlisberger, R., and Selmo, E. An oceanic cold reversal during the last deglaciation. Science 293, 5537 (2001). 2007420078.CrossRefGoogle ScholarPubMed
Stuiver, M., and Polach, H.A. Discussion: reporting of 14C data. Radiocarbon 19, 3 (1977). 355363.CrossRefGoogle Scholar
Taylor, S.P., Haywood, A.M., Valdes, P.J., and Sellwood, B.W. An evaluation of two spatial interpolation techniques in global sea-surface temperature reconstructions: Last Glacial Maximum and Pliocene case studies. Quaternary Science Reviews 23, (2004). 10411051.Google Scholar
Trusedell, A.H., (1976). GEOTHERM, a geothermometric computer program for hot springs systems: Proceeding 2nd UN Symposium on Development and Use of Geothermal Resources. San Francisco., (1975). v. 1, p. 831836.Google Scholar
USGS Fact Sheet, (1998). Ground-water quality in northern Ada County. lower Boise River Basin, Idaho, 1985–96: U.S. Department of the Interior, FS-054–98, pp. 16.Google Scholar
Vimeux, F., Cuffey, K., and Jouzel, J. New insights into Southern Hemisphere Temperature changes from the Vostok ice cores using deuterium excess correction. Earth and Planetary Science Letters 203, (2002). 829843.Google Scholar
Werner, M., and Heinmann, M. Modeling interannual variability of water isotopes in Greenland and Antarctica. Journal of Geophysical Research 107, D1 (2002). ACL 1, 113.Google Scholar
Wood, S.H., and Clemens, D.M. Geologic and tectonic history of the western Snake River Plain, Idaho and Oregon. Idaho Geological Survey Bulletin 30, (2002). 69103.Google Scholar
Zentner, M.A., (2001). Timing and mechanism of groundwater recharge in Mountainous terrain of a temperate climate.: unpublished M.S Thesis, Brigham Young University, Provo, UT., 105 p.Google Scholar
Supplementary material: PDF

Schlegel et al. supplementary Material

Supplementary Material

Download Schlegel et al. supplementary Material(PDF)
PDF 201.6 KB