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Isotopic evidence for temporal variation in proportion of seasonal precipitation since the last glacial time in the inland Pacific Northwest of the USA

Published online by Cambridge University Press:  20 January 2017

Akinori Takeuchi*
Affiliation:
School of Earth and Environmental Sciences, Washington State University, P.O. Box 642812, Pullman WA 99164-2812, USA
Angela J. Goodwin
Affiliation:
School of Earth and Environmental Sciences, Washington State University, P.O. Box 642812, Pullman WA 99164-2812, USA
Bryan G. Moravec
Affiliation:
School of Earth and Environmental Sciences, Washington State University, P.O. Box 642812, Pullman WA 99164-2812, USA
Peter B. Larson
Affiliation:
School of Earth and Environmental Sciences, Washington State University, P.O. Box 642812, Pullman WA 99164-2812, USA
C. Kent Keller
Affiliation:
School of Earth and Environmental Sciences, Washington State University, P.O. Box 642812, Pullman WA 99164-2812, USA
*
Corresponding author.

E-mail address:[email protected] (A. Takeuchi).

Abstract

Large-scale atmospheric circulation patterns determine the quantity and seasonality of precipitation, the major source of water in most terrestrial ecosystems. Oxygen isotope (δ18O) dynamics of the present-day hydrologic system in the Palouse region of the northwestern U.S.A. indicate a seasonal correlation between the δ18O values of precipitation and temperature, but no seasonal trends of δ18O records in soil water and shallow groundwater. Their isotope values are close to those of winter precipitation because the Palouse receives ∼ 75% of its precipitation during winter. Palouse Loess deposits contain late Pleistocene pedogenic carbonate having ca. 2 to 3‰ higher δ18O values and up to 5‰ higher carbon isotope (δ13C) values than Holocene and modern carbonates. The late Pleistocene δ18O values are best explained by a decrease in isotopically light winter precipitation relative to the modern winter-dominated infiltration. The δ13C values are attributed to a proportional increase of atmospheric CO2 in soil CO2 due to a decrease in soil respiration rate and 13C discrimination in plants under much drier paleoclimate conditions than today. The regional climate difference was likely related to anticyclonic circulation over the Pleistocene Laurentide and Ice Sheet.

Type
Research Article
Copyright
University of Washington

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Footnotes

1 Current address: Environmental Chemistry Division, National Institute for Environmental Studies, Tsukuba, Ibaraki 305-8506, Japan.
2 Current address: School of Natural Resources, University of Arizona, Tucson, AZ 85719, USA.

References

Alley, R.B., and Cuffey, K.M. Oxygen- and hydrogen-isotope ratios of water in precipitation: beyond paleothermometry. Valley, J.W., and Cole, D. Stable Isotope Geochemistry. Reviews in Mineralogy and Geochemistry vol 43, (2001). 527553.Google Scholar
Amundson, R.G., Chadwick, O.A., Sowers, J.M., and Doner, H.E. Relationship between climate and vegetation and the stable carbon isotope chemistry of soils in the eastern Mojave Desert, Nevada. Quaternary Research 29, (1988). 245254.CrossRefGoogle Scholar
Amundson, R., Chadwick, O., Kendall, C., Wang, Y., and DeNiro, M. Isotopic evidence for shifts in atmospheric circulation patterns during the late Quaternary in mid-North America. Geology 24, (1996). 2326.Google Scholar
Baker, V.R., Bjornstad, B.N., Busacca, A.J., Fecht, K.R., Kiver, E.P., Moody, U.L., Rigby, J.G., Stradling, D.F., and Tallman, A.M. Quaternary Geology of the Columbia Plateau. Morrison, R.B. Quaternary nonglacial geology: Conterminous U.S.. (1991). The Geological Society of America, Boulder, 215250.Google Scholar
Bartlein, P.J., Anderson, K.H., Anderson, P.M., Edwards, M.E., Mock, C.J., Thompson, R.S., Webb, R.S., Webb, T. III, and Whitlock, C. Paleoclimate simulations for North America over the past 21,000 years: features of the simulated climate and comparisons with paleoenvironmetal data. Quaternary Science Reviews 17, (1998). 549585.CrossRefGoogle Scholar
Berger, G.W., and Busacca, A.J. Thermoluminescence dating of late Pleistocene loess and tephra from eastern Washington and southern Oregon and implications for the eruptive history of Mount St. Helens. Journal of Geophysical Research 100, 22 (1995). 22362. 374 Google Scholar
Blinnikov, M., Busacca, A., and Whitlock, C. A new 100,000-year phytolith record from the Columbia Basin, Washington, USA. Meunier, J.D., and Colin, F. Phytoliths: Applications in Earth Sciences and Human History. (2001). A.A. Balkema, Lisse. 2755.Google Scholar
Busacca, A. Long Quaternary record in eastern Washington, U.S.A., interpreted from multiple buried paleosols in loess. Geoderma 45, (1989). 105122.Google Scholar
Busacca, A.J., Nelstead, K.T., McDonald, E.V., and Purser, M.D. Correlation of distal tephra layers in loess in the Channeled Scabland and Palouse of Washington State. Quaternary Research 37, (1992). 281303.Google Scholar
Cerling, T.E. Carbon dioxide in the atmosphere: evidence from Cenozoic and Mesozoic paleosols. American Journal of Science 291, (1991). 377400.Google Scholar
Cerling, T.E., and Quade, J. Stable carbon and oxygen isotopes in soil carbonates. Swart, P.K., Lohmann, K.C., McKenzie, J., and Savin, S. Climate Change in Continental Isotopic Records. American Geophysical Union Geophysical Monograph vol. 78, (1993). 217231.Google Scholar
Daubenmire, R. Steppe Vegetation of Washington. Washington Agricultural Experiment Station Technical bulletin 62. (1970). Washington State University, Pullman.Google Scholar
Dawson, T.E., Mambelli, S., Plamboeck, A.H., Templer, P.H., and Tu, K.P. Stable isotopes in plant ecology. Annual Review of Ecology, Evolution, and Systematics 33, (2002). 507559.Google Scholar
Deines, P., Langmuir, D., and Harmon, R.S. Stable Carbon isotope ratios and the existence of a gas phase in the evolution of carbonate ground waters. Geochimica et Cosmochimica Acta 38, (1974). 11471164.Google Scholar
Feng, X., Reddington, A.L., Faiia, A.M., Posmentier, E.S., Shu, Y., and Xu, X. The changes in North American atmospheric circulation patterns indicated by wood cellulose. Geology 35, (2007). 163166.CrossRefGoogle Scholar
Friedman, I., O'Neil, J.R., (1977). Compilation of stable isotope fractionation factors of geochemical interest. U.S Geological Survey Professional Paper 440-KK, Washington D.C..Google Scholar
Gat, J.R., and Bowser, C. The heavy isotope enrichment of water in coupled evaporative systems. Taylor, H.P. Jr., O'Neil, J.R., and Kaplan, I.R. Stable Isotope Geochemistry: A Tribute to Samuel Epstein. The Geochemical Society Special Publication vol. 3, (1991). 159168.Google Scholar
Goodwin, A.J., (2006). Oxygen-18 in surface and soil waters in a dryland agricultural setting, Eastern Washington: flow processes and mean residence times at various watershed scales. Washington State University, Pullman. (M.S. Thesis).Google Scholar
Hearn, P.P. Jr., Steinkampf, W.C., Horton, D.G., Solomon, G.C., White, L.D., and Evans, J.R. Oxygen-isotope composition of groundwater and secondary minerals in Columbia Plateau basalts: implications for the paleohydrology of the Pasco Basin. Geology 17, (1989). 606610.Google Scholar
Hsieh, J.C.C., Chadwick, O.A., Kelly, E.F., and Savin, S.M. Oxygen isotopic composition of soil water: quantifying evaporation and transpiration. Geoderma 82, (1998). 269293.Google Scholar
Keller, C.K., Butcher, C.N., Smith, J.L., and Allen-King, R.M. Nitrate in tile drainage of the semiarid Palouse basin. Journal of Environmental Quality 37, (2008). 353361.Google Scholar
Kutzbach, J.E., Guetter, P.J., Behling, P.J., and Selin, R. Simulated climatic changes: results of the COHMAO climate-model experiments. Wright, H.E. Jr Global Climates Since the Last Glacial Maximum. (1993). University of Minnesota Press, Minneapolis, MN. 2493.Google Scholar
Larson, K.R., Keller, C.K., Larson, P.B., and Allen-King, R.M. Water resource implications of 18O and 2H distributions in a basalt aquifer system. Ground Water 38, (2000). 947953.Google Scholar
Marino, B.D., McElroy, M.B., Salawitch, R.J., and Spaulding, W.G. Glacial-to-interglacial variations in the carbon isotopic composition of atmospheric CO2. Nature 357, (1992). 461466.Google Scholar
McDonald, E.V., and Busacca, A.J. Interaction between aggrading geomorphic surfaces and the formation of a late Pleistocene paleosol in the Palouse loess of eastern Washington state. Knuepfer, P.L.K., and McFadden, L.D. Soils and Landscape Evolution. Geomorphology vol. 3, (1990). 449470.Google Scholar
McDonald, E.V., and Busacca, A.J. Late Quaternary stratigraphy of loess in the Channeled Scabland and Palouse regions of Washington State. Quaternary Research 38, (1992). 141156.Google Scholar
Mullineaux, D.R. Summary of pre-1980 tephra-fall deposits from Mount St. Helens, Washington State, USA. Bulletin of Volcanology 48, (1986). 1726.Google Scholar
O'Geen, A.T., and Busacca, A.J. Faunal burrows as indicators of paleo-vegetation in eastern Washington, USA. Palaeogeography, Palaeoclimatology, Palaeoecology 169, (2001). 2337.Google Scholar
Poage, M.A., Sjostrom, D.J., Goldberg, J., Chamberlain, C.P., and Furniss, G. Isotopic evidence for Holocene climate change in the northern Rockies from a goethite-rich ferricrete chronosequence. Chemical Geology 166, (2000). 327340.Google Scholar
Quade, J., Cerling, T.E., and Bowman, J.R. Systematic variations in the carbon and oxygen isotopic composition of pedogenic carbonate along elevation transects in the southern Great Basin, United States. Geological Society of America Bulletin 101, (1989). 464475.Google Scholar
Raich, J.W., and Schlesinger, W.H. The global carbon dioxide flux in soil respiration and its relationship to vegetation and climate. Tellus 44B, (1992). 8199.CrossRefGoogle Scholar
Richardson, C.A., McDonald, E.V., and Busacca, A.J. Luminescence dating of loess from the Northwest United States. Quaternary Science Reviews 16, (1997). 403415.Google Scholar
Robertson, J.A., and Gazis, C.A. An oxygen isotope study of seasonal trends in soil water fluxes at two sites along a climate gradient in Washington State (USA). Journal of Hydrology 328, (2006). 375387.Google Scholar
Rozanski, K., Araguas-Araguas, L., and Gonfiantini, R. Isotopic patterns in modern global precipitation. Swart, P.K., Lohmann, K.C., McKenzie, J., and Savin, S. Climate Change in Continental Isotopic Records. American Geophysical Union Monograph vol. 78, (1993). 136.Google Scholar
Schaetzl, R.J., and Anderson, S Soils. (2005). Cambridge Univ. Press, New York, Genesis and Geomorphology.Google Scholar
Sjostrom, D.J., Hren, M.T., and Chamberlain, C.P. Oxygen isotope records of goethite from ferricrete deposits indicate regionally varying Holocene climate change in the Rocky Mountain region, U.S.A. Quaternary Research 61, (2004). 6471.CrossRefGoogle Scholar
Soil Survey Staff Keys to Soil Taxonomy. 9th ed. (2003). U.S. Department of Agriculture Natural Resources Conservation Service, Washington, D.C..Google Scholar
Stevenson, B.A., (1997). Stable carbon and oxygen isotopes in soils and paleosols of the Palouse loess eastern Washington State: modern relationships and applications for paleoclimatic reconstruction. Colorado State University, Fort Collins. (Ph.D. Dissertation).Google Scholar
Stevenson, B.A., Kelly, E.F., McDonald, E.V., and Busacca, A.J. The stable carbon isotope composition of soil organic carbon and pedogenic carbonates along a bioclimatic gradient in the Palouse region, Washington State, USA. Geoderma 124, (2005). 3747.Google Scholar
Sweeney, M.R., Busacca, A.J., and Gaylord, D.R. Topographic and climatic influences on accelerated loess accumulation since the last glacial maximum in the Palouse, Pacific Northwest, USA. Quaternary Research 63, (2005). 261273.Google Scholar
Sweeney, M.R., Busacca, A.J., Richardson, C.A., Blinnikov, M., and McDonald, E.V. Glacial anticyclone recorded in Palouse loess of northwestern United States. Geology 32, (2004). 705708.Google Scholar
Thompson, R.S., Whitlock, C., Bartlein, P.J., Harrison, S.P., and Spaulding, W.G. Climatic changes in the western United states since 18,000 yr BP. Wright, H.E. Jr., Kutzbach, J.E., Webb, T. III, Ruddiman, W.F., Street-Perrott, F.A., and Bartlein, P.J. Global Climates Since the Last Glacial Maximum. (1993). University of Minnesota Press, Minneapolis, MN. 468513.Google Scholar
Whitlock, C., Sarna-Wojcicki, A.M., Bartlein, P.J., and Nickmann, R.J. Environmental history and tephrostratigraphy at Carp Lake, southwestern Columbia Basin, Washington, USA. Palaeogeography, Palaeoclimatology, Palaeoecology 155, (2000). 729.Google Scholar
Whitlock, C., Bartlein, P.J., and Markgraf, V. The midlatitudes of North and South America during the last glacial maximum and early Holocene: similar paleoclimate sequences despite differing large-scale controls. Markgraf, V. Interhemispheric Climate Linkages. (2001). Academic Press, San Diego. 391416.Google Scholar