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Paleohydrologic Regimes in the Southwestern Great Basin, 0–3.2 my ago, Compared with Other Long Records of “Gobal” Climate

Published online by Cambridge University Press:  20 January 2017

George I. Smith*
Affiliation:
U.S. Geological Survey, Menlo Park, California 94025

Abstract

Nine distinct paleohydrologic regimes in the southwestern Great Basin over the last 3.2 my are recorded by the lacustrine deposits in KM-3, a 930-m core from Searles Lake, California. These are characterized as being “wet,” “intermediate,” or “dry” (like today). Excepting the present incomplete regime, each lasted 0.12 to 0.76 my. Major regime changes 0.01, 0.13, 0.6, and 2.5 my ago appear to coincide with recognized changes in global ice-sheet histories as represented by 18O and other records from marine sediments, but comparable changes 0.3, 1.0, 1.3, and 2.0 my ago do not appear to coincide closely with comparable perturbations in ice-sheet histories. However, all regime boundaries (during the last 1.75 my) coincide closely in time with changes in sea-surface temperatures in the tropical Atlantic, and many coincide with other deep-sea and continental paleoclimatic boundaries.The average duration of these paleohydrologic regimes was about 0.4 my (standard deviation, 0.2 my or less, depending on assumptions), and it is suggested that the regime boundaries reflect times of change in global(?) sea-surface temperatures, possibly controlled in part by the Earth's 413,000-yr orbital eccentricity cycle. During the wettest and driest regimes in the Searles Lake area, lake levels were not sufficiently affected by the 23,000-, to 42,000-, or 100,000-yr climate cycles related to high-latitude ice-sheet fluctuations to produce changes in the lacustrine sediment character. During intermediate regimes, however, when lacustrine sedimentation in this area was more sensitive to climate, the sediments, in KM-3, record lake fluctuations with average frequencies near those of the ice sheets. This seems to indicate that the high-latitude ice-sheet fluctuations caused local climatic perturbations but did not dominate the hydrologic component of climate in this area. Other lacustrine deposits in the southwestern Great Basin of California and Nevada have ages comparable in part to those of the wet to intermediate regimes indicated by KM-3, and they may all be products of finite periods when lake expansion, alluvial fan growth, increased spring discharge, and fluvial deposition were promoted in this area by widespread wet climates. Glacier expansion in the Sierra Nevada may also have been primarily an expression of, and in phase with, these wet regimes.

Type
Research Article
Copyright
University of Washington

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References

Bailey, R.A. Dalrymple, B.G. Lanphere, M.A. (1976). Volcanism, structure, and geochronology of Long Valley Caldera, Mono County, California Journal of Geophysical Research 81 725 744 Google Scholar
Briskin, M. Berggren, W.A. (1975). Pleistocene stratigraphy and quantitative paleo-oceanography of tropical North Atlantic core V16-205 Late Neogene boundaries Saito, T. Burckle, L.H. Special Publication No. 1 American Museum of Natural History, Micropaleontology Press New York 167 198 Google Scholar
Duffield, W.A. Bacon, C.R. (1981). Geologic Map of the Coso Volcanic Field and Adjacent Areas, Inyo County, California U.S. Geological Survey Miscellaneous Investigations Series Map I-1200Google Scholar
Duffield, W.A. Smith, G.I. (1978). Pleistocene history of volcanism and the Owens River near Little Lake, California Journal of Research of the U.S. Geological Survey 6 395 408 Google Scholar
Eardley, A.J. Gvosdetsky, V. (1960). Analysis of Pleistocene core from Great Salt Lake, Utah Geological Society of America Bulletin 71 1323 1344 CrossRefGoogle Scholar
Eardley, A.J. (1973). Lake cycles in the Bonneville Basin, Utah Geological Society of America Bulletin 84 211 216 2.0.CO;2>CrossRefGoogle Scholar
Erickson, D.B. Wollin, G. (1968). Pleistocene climates and chronology in deep-sea sediments Science 162 1227 1234 Google Scholar
Gilbert, C.M. Christensen, M.N. Al-Rawi, Y. Lajoie, K.R. (1969). Structural and volcanic history of Mono Basin, California-Nevada Studies in Volcanology: A memoir in Honor of Howel Williams Coats, R.R. Hay, R.L. Anderson, C.A. Geological Society of America, Memoir 116 275 329 Google Scholar
Hays, J.D. Imbrie, J. Shackleton, N.J. (1976). Variations in the Earth's orbit: Pacemaker of the ice ages Science 194 1121 1132 Google Scholar
Herman, Y. Hopkins, D.M. (1980). Arctic oceanic climate in late Cenozoic time Science 209 557 562 Google Scholar
Hoover, D.L. Hay, R.L. Hillhouse, J.W. (1982). Paleoclimates of the Amargosa Basin, Nevada-California Abstracts with Programs, Geological Society of America, Cordilleran Section, Anaheim, California 173 Google Scholar
Huber, N.K. (1981). Amount and Timing of Late Cenozoic Uplift and Tilt on the Central Sierra Nevada, Caifornia-Evidence from the Upper San Joaquin River Basin U.S. Geological Survey Professional Paper 1197Google Scholar
Huber, N.K. Rinehart, C.D. (1967). Cenozoic Volcanic Rocks of the Devils Postpile Quadrangel, Eastern Sierra Nevada, California U.S. Geological Survey Professional Paper 554-DGoogle Scholar
Izett, G.A. (1981). Volcanic ash beds: Recorders of upper Cenozoic silicic pyroclastic volcanism in the Western United States Journal of Geophysical Research 86 10200 10222 CrossRefGoogle Scholar
Izett, G.A. Wilcox, R.E. Powers, H.A. Desborough, G.A. (1970). The Bishop ash bed, a Pleistocene marker bed in the western United States Quaternary Research 1 121 132 Google Scholar
Kukla, G. (1978). The classical European glacial stages: Correlation with deep-sea sediments Transactions of the Nebraska Academy of Sciences 6 57 93 Google Scholar
Liddicoat, J.C. Opdyke, N.D. Smith, G.I. (1980). Palaeomagnetic polarity in a 930-m core from Searles Valley, California Nature (London) 286 22 26 Google Scholar
Moore, R.C. Pisais, N.G. Dunn, D.A. (1982). Carbonate time series of the Quaternary and late Miocene sediments in the Pacific Ocean: A spectral comparison Marine Geology 46 217 233 Google Scholar
Negrini, R. Davis, J.O. Verosub, K.L. (1981). Secular variation during a 250,000 year interval in the middle Pleistocene as recorded by lake sediments in Northern Nevada EOS, Transactions American Geophysical Union 62 851 Google Scholar
Prell, W.L. (1982). Oxygen and carbon isotope stratigraphy for the Quaternary of hole 502B: Evidence for two modes of isotopic variability Amidei, R. Lee, M. Initial Reports of the Deep Sea Drilling Project Vol. LXVIII University of California, Scripps Institution of Oceanography La Jolla 455 464 Google Scholar
Repenning, C. A. (in press a). Biochronology of the microtine rodents of the United States. In “Cenozoic mammals: Their temporal record, biostratigraphy, and biochronology” (Woodburne, M. O. Ed.), Univ. of California Press, Berkeley.Google Scholar
Repenning, C. A. (in press b). Pleistocene mammalian faunas: Climate and evolution. Acta Zoologica Fennica .Google Scholar
Shackleton, N.J. Opdyke, N.D. (1973). Oxygen isotope and paleomagnetic stratigraphy of equatorial Pacific core V28-238: Oxygen isotope temperatures and ice volumes on a 105 year and 105 year scale Quaternary Research 3 39 55 Google Scholar
Shackleton, N.J. Opdyke, N.D. (1976). Oxygen isotope and paleomagnetic stratigraphy of Pacific core V28-239, late Pliocene to latest Pleistocene Investigations of Late Quaternary Paleoceanography and Paleoclimatology Cline, R.M. Hays, J.D. Geological Society of America, Memoir 145 449 464 Google Scholar
Shackleton, N.J. Opdyke, N.D. (1977). Oxygen isotope and palaeomagnetic evidence for early Northern Hemisphere glaciation Nature (London) 270 216 219 CrossRefGoogle Scholar
Sheppard, R.A. Gude, A.J. (1968). Distribution and Genesis of Authigenic Silicate Minerals in Tuffs of Pleistocene Lake Tecopa, Inyo County, California 597 U.S. Geological Survey Professional PaperGoogle Scholar
Smith, G.I. (1968). Late Quaternary geologic and climatic history of Searles Lake, southeast California Morrison, R.B. Wright, H.E. Jr. Means of Correlation of Quaternary Successions Vol. 8 Univ. of Utah Press Salt Lake City 293 310 Google Scholar
Smith, G.I. (1979). Subsurface Stratigraphy and Geochemistry of Late Quaternary Evaporites, Searles Lake, California U.S. Geological Survey Professional Paper 1043Google Scholar
Smith, G.I. Barczak, V.J. Moulton, G.F. Liddicoat, J.C. (1983). Core KM-3, a Surface-to-Bedrock Record of Late Cenozoic Sedimentation in Searles Valley, California U.S. Geological Survey Professional Paper 1256Google Scholar
Smith, G.I. Street-Perrott, F.A. (1983). Pluvial lakes of the western United States Wright, H.E. Jr. Late-Quaternary Environments of the United States Univ. of Minnesota Press Minneapolis 190 211 chap 10Google Scholar
Stuiver, M. Smith, G.I. (1979). Radiocarbon ages of stratigraphic units Subsurface Stratigraphy and Geochemistry of late Quaternary Evaporites, Searles Lake, California Smith, G.I. U.S. Geological Survey Professional Paper 1043 68 75 Google Scholar
van Donk, J. (1976). O18 record of the Atlantic Ocean for the entire Pleistocene epoch Investigations of Late Quaternary Paleoceanography and Paleoclimatology Cline, R.M. Hays, J.D. Geological Society of America Memoir 145 147 163 CrossRefGoogle Scholar
Zubakov, V.A. Borzenkova, I.I. (1983). Paleoclimates of the Upper Cenozoic Gidrometeoizdat Leningrad [in Russian; English summary]Google Scholar