Hostname: page-component-cd9895bd7-dk4vv Total loading time: 0 Render date: 2024-12-23T02:02:13.082Z Has data issue: false hasContentIssue false

The Late Quaternary Climate of Coastal California: Evidence for an Ice Age Refugium1

Published online by Cambridge University Press:  20 January 2017

Donald Lee Johnson*
Affiliation:
Department of Geography, University of Illinois, Urbana, Illinois 61801

Abstract

The present Mediterranean climate of coastal California is unique in North America and reflects the interaction of several important synoptic controls, principally the North Pacific semipermanent anticyclone, and to a lesser extent the Aleutian low-pressure system and the cool California oceanic current. These synoptic climatic controls, key parts of the global air-sea circulation, were probably operative throughout late Quaternary time as shown by paleoecologic evidence. The thick accumulations of sediments in basins of offshore California indicate that while variable sedimentation regimes reflect changing climatic and oceanographic conditions, the Quaternary climate was probably semiarid as now, even during glacial maxima. Late Quaternary coastal dunes preserve former wind directions and show that prevailing late Quaternary winds were directionally equivalent to modern winds, which are controlled by the North Pacific anticyclone and by interactions between the North Pacific high and the interior basin low. These sand dunes contain buried, datable, carbonate-rich soils. Precipitation then, like the present rainfall regime, was not enough to leach the carbonates from the soils. Charcoal in buried dunes and soils shows that fire was environmentally important throughout the Quaternary, just as it is today. Fossil plants indicate that sclerophyllous vegetation and forest stands of conifers, adapted to a Mediterranean climate, were widely distributed during late Quaternary time. Fossil pollen in the Sierra Nevada indicates the influence of the North Pacific high. The historical precipitation record overlaps a late Holocene tree-ring record permitting extrapolation of the precipitation curve back nearly 600 years. Well-defined wet and dry trends in the precipitation pattern characterized this time span, and provide a possible analog to the earlier Holocene and Pleistocene precipitation regime. The paleoecologic record shows that the late Quaternary climate of coastal California was characterized by regimes similar to those prevailing today. The persistence of a Mediterranean climate in California during the last glaciation contrasts with dramatic climatic changes experienced in glaciated parts of North America. California thus was an Ice Age refugium for animals and cold-sensitive plants.

Type
Research Article
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.)

Footnotes

1

This paper is an appreciably modified part of a version presented at the Proceedings of the Ninth International Congress of Anthropologists and Ethnologists, held during August-September, 1973, at Chicago, Illinois.

References

Adam, D.P., (1967). Late-Pleistocene and Recent palynology in the central Sierra Nevada, California. Cushing, E.J., Wright, H.E. Jr., Quaternary Paleoecology. Yale Univ. Press, New Haven, 275-301.Google Scholar
Adam, D.P., (1973). Early Pleistocene (?) pollen spectra from near Lake Tahoe, California. U. S. Geological Survey Journal of Research. 1, 691-693.Google Scholar
Adam, D.P., (1975). A late Pleistocene pollen record from Pearson's Pond, Week's Creek landslide, San Francisco Peninsula, California. U. S. Geological Survey Journal of Research. 3, 721-731.Google Scholar
Addicott, W., (1966) Late Pleistocene Marine Paleoecology and Zoogeography in Central California. U. S. Government Printing Office, Washington, D.C, Geological Survey Professional Paper 523-C.Google Scholar
Axelrod, D.I., (1966) The Pleistocene Soboba Flora of Southern California. Univ. of California Press, Berkeley, 1-109 University of California Publications in Geological Sciences 60.Google Scholar
Axelrod, D.I., 1967a. Evolution of the Californian closed-cone pine forest. Philbrick, R.N., Proceedings of the Symposium on the Biology of the California Islands. Santa Barbara Botanic Garden, Santa Barbara, 93-149.Google Scholar
Axelrod, D.I., 1967b. Geologic history of the Californian insular flora. Philbrick, R.N., Proceedings of the Symposium on the Biology of the California Islands. Santa Barbara Botanic Garden, Santa Barbara, 267-315.Google Scholar
Berger, R., Libby, W., (1966). UCLA Radiocarbon dates 43. Radiocarbon. 8, 467-497.Google Scholar
Birman, J.H., (1964) Glacial Geology across the Crest of the Sierra Nevada, California. Geological Society of American Special Paper 75.Google Scholar
Broecker, W.S., Kulp, J.L., Tucek, C.S., (1956). Lamont natural radiocarbon measurements III. Science. 124, 154-165.Google Scholar
Bryson, R.A., (1973) Climatic Modification By Air Pollution, II: The Sahelian Effect. University of Wisconsin, The Institute for Environmental Studies, Report 9.Google Scholar
Bryson, R.A., Hare, F.K., (1974). The climates of North America. Bryson, R.A., Hare, F.K., World Survey of Climatology. Elsevier, New York, 1-47.Google Scholar
Bryson, R.A., Wendland, W.M., (1967). Tentative climatic patterns for some late glacial and post-glacial episodes in central North America. Mayer-Oakes, W.J., Life, Lang and Water. Univ. of Manitoba Press, Winnipeg, 271-298.Google Scholar
Butzer, K., (1963). Climatic-geomorphic interpretation of Pleistocene sediments in the Eurafrican subtropics. Viking Fund Publications in Anthropology. 36, 1-27.Google Scholar
Chaney, R.W., (1933). A Pleistocene flora from the asphalt deposits at Carpinteria, California. Carnegie Institution of Washington Publication. 415, 47-79.Google Scholar
Chaney, R.W., Mason, H.L., (1930). A Pleistocene flora from Santa Cruz Island, California. Carnegie Institution of Washington Publication. 415, 1-24.Google Scholar
Cooper, W.S., (1967). Coastal dunes of California. Geological Society of America, Memoir. 104.CrossRefGoogle Scholar
Curry, R.R., (1969). Holocene climatic and glacial history of the central Sierra Nevada, California. Geological Society of America, Special Papers. 123, 1-47.CrossRefGoogle Scholar
Deevey, E.S., Flint, R.F., (1957). Postglacial Hypsothermal interval. Science. 125, 182-184.Google Scholar
Deevey, E.S., Gralenski, L.J., Hoffren, 44., (1959). Yale natural radiocarbon measurements, IV. Radiocarbon. 1, 144-172.Google Scholar
DeMarrais, G.A., Holzworth, G.C., Hosler, C.R., (1965) Meteorological Summaries Pertinent to Atmospheric Transport and Dispersion over Southern California. U. S. Government Printing Office, Washington, D. C, U. S. Department of Commerce, Weather Bureau Technical Paper No. 54.Google Scholar
De Violini, R., (1967) Climatic Handbook for Point Mugu and San Nicolas Island. Volume I: Surface Data. Pacific Missile Range Miscellaneous Report PMR-MR-67-2. Point Mugu, California.Google Scholar
Dodge, M., (1970). Fire control of chaparral. Science. 168, 420.Google Scholar
Douglas, A.45., (1973). Past Air-Sea Interactions off Southern California as Revealed by Tree-Ring Chronologies. M.A. Thesis. Univ. of Arizona, Tucson, Arizona. Google Scholar
Douglas, A.46., (1976). Past Air-Sea Interactions over the Eastern North Pacific Ocean as Revealed by Tree-Ring Data. Ph.D. Thesis. Univ. of Arizona, Tucson, Arizona. Google Scholar
Douglas, D., (1952). Measuring low-level radioactivity. General Electric Review. 55, 16-20.Google Scholar
Drake, D.E., Kolpack, R.L., Fisher, P.J., (1972). Sediment transport on the Santa Barbara-Oxnard shelf, Santa Barbara Channel, California. Swift, D.J.P., Pilkey, H., Duane, D.B., Shelf Sediment Transport. Hutchinson and Ross, Stroudsburg, 307-331.Google Scholar
Eardley, A.J., Shuey, R.T., Gvosdetsky, 47., Nash, W.P., Dane Picard, M., Gray, D.C., Kukla, G.J., (1973). Lake cycles in the Bonneville Basin, Utah. Geological Society of America Bulletin. 84, 211-216.2.0.CO;2>CrossRefGoogle Scholar
Emery, K.O., (1960) The Sea Off Southern California. Wiley, New York. Google Scholar
Fairbridge , R. W., and Johnson , D. L., (in press).Eolianite. . In “Encyclopedia of Sedimentology”. ( Fairbridge , R. W., Ed.). Dowden, Hutchinson and Ross, , Stroudsburg. .Google Scholar
Fergusson, G.J., Libby, W.F., (1963). UCLA radiocarbon dates, II. Radiocarbon. 5, 1-22.Google Scholar
Fergusson, G.J., Libby, W.F., (1964). UCLA radiocarbon dates, III. Radiocarbon. 6, 318-339.Google Scholar
Flohn, H., (1965). Problems der theoretischen klimatologie. Naturwissenschaftliche Rundchau. Band 18, 385-392 Heft 10.Google Scholar
Frost, F.H., (1927). The Pleistocene flora of Rancho La Brea. University of California Publications in Botany. 14, 73-98.Google Scholar
Gates, W.L., (1976). Modeling the Ice Age climate. Science. 191, 1138-1144.Google Scholar
Gorsline, D.S., Drake, D.E., Barnes, P.W., (1968). Holocene sedimentation in Tanner Basin, California Continental Borderland. Geological Society of America Bulletin. 79, 659-674.Google Scholar
Gorsline, D.S., Barnes, P.W., (1972). Carbonate variations as climatic indicators in contemporary California flysch basins. 24th International Geologic Congress, Section 6. Montreal 270-277.Google Scholar
Gorsline, D.S., Prensky, S.E., (1975). Paleoclimatic inferences for late Pleistocene and Holocene from California Continental Borderland basin sediments. Suggate, R.P., Cresswell, M.M., Quaternary Studies. The Royal Society of New Zealand, Wellington, 147-154.Google Scholar
Gorsline, D.S., Pao, G.A., Prensky, S.E., Mulhern, M., (1976). High resolution studies of paleo-climatic and paleo-oceanographic history in California Continental Borderland basin sediments. Program, American Association of Petroleum Geologists—Society of Economic Paleontologists and Mineralogists, Annual Meeting. New Orleans 68.Google Scholar
Gorsline , D. S., and Pao , G. A., (in press).High resolution studies of basin sedimentation related to climatic-oceanographic changes over the past 50,000 years in the California Continental Borderland. ..Google Scholar
Heath, G.R., Dauphin, J.P., Opdyke, N.D., Moore, T.C., (1973). Distribution of quartz, opal, calcium carbonate and organic carbon in Holocene, 600,000 and Brunhes/Matuyama age sediments of the North Pacific. Geological Society of American Abstracts with Programs. 5, 662.Google Scholar
Ho, T.Y., Marcus, L.F., Berger, R., (1969). Radiocarbon dating of petroleum-impregnated bone from tar pits at Rancho La Brea, California. Science. 164, 1051-1052.Google Scholar
Holzworth, G.C., (1973). Large-scale weather influences on community air pollution potential in the United States. McBoyle, G., Climate in Review. Houghton Mifflin, Boston, 241-248.Google Scholar
Howard, H., (1960). Significance of carbon-14 dates for Rancho La Brea. Science. 131, 712-714.Google Scholar
Hubbs, C.L., Bien, G.S., Suess, H., (1960). La Jolla natural radiocarbon measurements, I. Radiocarbon. 2, 197-223.Google Scholar
Johnson, D.L., (1967) Caliche on the Channel Islands. 20, Mineral Information Service, California Division of Mines and Geology, 151-158.Google Scholar
Johnson, D.L., (1968). Quaternary coastal eolianites: Do they have ancient analogs?. Programs with Abstracts, Geological Society of America 1968 Annual Meetings. Mexico City 150-151.Google Scholar
Johnson, D.L., (1972). Landscape Evolution on San Miguel Island, California. Ph.D. Thesis. Univ. of Kansas, Lawrence, Kansas, Also.Google Scholar
Johnson, D.L., Dissertation Abstracts. Order No. 73-11,902.Google Scholar
Johnson , D. L., (in prep.).A late Quaternary closed-cone pine florula and associated components from San Miguel Island. , California. .Google Scholar
Kheradpir, A., (1970). Foraminiferal trends in the Quaternary of Tanner Basin, California. Micropaleontology. 16, 102-116.Google Scholar
Langenheim, H.H., Durham, J.W., (1963). Quaternary closed-cone pine flora from travertine near Little Sur, California. Madroño. 17, 33-51.Google Scholar
Leskinen, P.H., (1970). Late Pleistocene Vegetation Change in the Christmas Tree Pass area, Newberry Mountains, Nevada. M.S. Thesis. Univ. of Arizona, Tucson. Google Scholar
Leskinen, P.H., (1975). Occurrence of oaks in late Pleistocene vegetation in the Mojave Desert of Nevada. Madroño. 23, 234-235.Google Scholar
Linhart, Y.B., Burr, B., Conkle, J.T., (1967). The closed-cone pines of the Northern Channel Islands. Philbrick, R.N., Proceedings of the Symposium on the Biology of the California Islands. Santa Barbara Botanic Garden, Santa Barbara, 151-177.Google Scholar
McBurney, C., Hey, R., (1955) Prehistory and Pleistocene Geology in Cyrenaican Libya. Cambridge Univ. Press, Cambridge. Google Scholar
MacKenzie, F.T., (1964). Bermuda Pleistocene eolianites and paleowinds. Sedimentology. 3, 52-64.Google Scholar
McIntyre, A., (1976). CLIMAP Project Members. The surface of the Ice Age earth. . Science. 191, 1131-1137.Google Scholar
Mason, H.L., (1927). Fossil records of some west American conifers. Carnegie Institute of Washington Publication. 346, 139-158.Google Scholar
Mason, H.L., (1932). A phylogenetic series of the California closed-cone pines suggested by the fossil record. Madroño. 2, 49-55.Google Scholar
Mason, H.L., (1934). Pleistocene flora of the Tomales Formation. Carnegie Institution of Washington Publication. 415, 81-179.Google Scholar
Mason, H.L., (1940). A Pleistocene record of Pseudotsuga macrocarpa. Madroño. 5, 233-235.Google Scholar
Mason, H.L., (1944). A Pleistocene flora from the McKittrick asphalt deposits of California. Proceedings of the California Academy of Sciences (4th Series). 25, 221-233.Google Scholar
Moran, J.M., (1972). An Analysis of Periglacial Climatic Indicators of Late Glacial Time in North America. Ph.D. Thesis. Univ. of Wisconsin, Madison. Google Scholar
Moran, J.M., (1975). Glacial Maximum Tundra: A Bioclimatic Anomaly. Paper presented at Australasian Conference on Climate and Climatic Change. Monash University, Clayton, Victoria, Australia, December 7–12, 1975 .Google Scholar
Morin, R.W., (1971). Late Quaternary biostratigraphy of cores from beneath the California current. Micropaleontology. 17, 475-491.CrossRefGoogle Scholar
Morrison, R.B., (1965) Frye, J.C., Correlation of the Middle and Quaternary Successions of the Lake Lahontan, Lake Bonneville, Rocky Mountain (Wasatch Range), Southern Great Plains, and Eastern Midwest Areas. Nevada Bureau of Mines Report 9.Google Scholar
Moseley, F., (1965). Plateau calcrete, calcreted gravels, cemented dunes, and related deposits of the Maallegh-Bomba region of Libya. Zeitschrift für Geomorphologie. 9, 166-185.Google Scholar
Munz, P.A., (1959) A California Flora. Univ. of California Press, Berkeley. Google Scholar
Namias, J., (1960). The meteorological picture 1957–1958. Symposium on the Changing Pacific Ocean in 1957 and 1958. California Marine Research Commission, CalCOFI Report 7. 33-41.Google Scholar
Orr, P.C., (1967). Geochronology of Santa Rosa Island, California. Philbrick, R.N., Proceedings of the Symposium on the Biology of the California Islands. Santa Barbara Botanic Garden, Santa Barbara, 317-325.Google Scholar
Orr, P.C., (1968) Prehistory of Santa Rosa Island. Santa Barbara Museum of Natural History, Santa Barbara. Google Scholar
Orr, P.C., Berger, R., (1966). The fire areas on Santa Rosa Island, California, I. Proceedings of National Academy of Sciences. 56, 1409-1416.Google Scholar
Phillips, A.M. III, Van Devender, T.R., (1974). Pleistocene packrat middens from the lower Grand Canyon of Arizona. Journal of the Arizona Academy of Science. 9, 117-119.Google Scholar
Phillips, A.M. III, (1976). Packrats, plants and the Pleistocene in the lower Grand Canyon of Arizona. Abstracts, American Quaternary Association, Fourth Biennial Meeting. Tucson 70-71.Google Scholar
Potbury, S., (1932). A Pleistocene flora from San Bruno, San Mateo County, California. Carnegie Institution of Washington Publication. 415, 25-44.Google Scholar
Reid, J.L., (1960). Oceanography of the eastern North Pacific in the last 10 years. Symposium on the Changing Pacific Ocean in 1957 and 1958. California Marine Research Commission, CalCOFI Report 7. 77-90.Google Scholar
Roden, G.I., (1958). Spectral analysis of a sea-surface temperature and atmospheric pressure record off Southern California. Journal of Marine Research. 16, 90-95.Google Scholar
Schulman, E., (1947). Tree-ring hydrology in southern California. Laboratory of Tree-ring Research Bulletin. 4.Google Scholar
Schulman, E., Tree-ring hydrology in southern California. University of Arizona Bulletin. 18, 1-36.Google Scholar
Smagorinsky, J., (1963). General circulation experiments with the primitive equations, I: The basic experiment. Monthly Weather Review. 91, 99-164.2.3.CO;2>CrossRefGoogle Scholar
Smith, G.I., (1968). Late-Quaternary geologic and climatic history of Searles Lake, southeastern California. Morrison, R.B., Wright, H.E., Means of Correlation of Quaternary Successions. Univ. of Utah Press, Salt Lake City, 293-310.Google Scholar
Smith, G.I., (1970). Late Wisconsin lake fluctuations in Searles Valley, California. Abstracts, American Quaternary Association, First Biennial Meeting. Bozeman 124.Google Scholar
Smith , G. I., (in press).Paleoclimatic record in the upper Quaternary sediments of Searles Lake, California, U. S. A. . Paleolimnology of Lake Biwa and the Japanese Pleistocene . 4..Google Scholar
Spaulding , W. G., (in press).Late Quaternary vegetational change in the Sheep Range, southern Nevada. . Journal of the Arizona Academy of Science . ..Google Scholar
Stock, C., (1958). Rancho La Brea; a record of Pleistocene life in California. Los Angeles Museum Science Series No. 20. Paleontology. 11.Google Scholar
Stone, E.C., Vasey, R.B., (1962) Redwood Ecology. School of Forestry, Univ. of California, Berkeley, Annual Report.Google Scholar
Templeton, B., (1955). Fossil plants in the La Brea deposits. Los Angeles County Museum Quarteryly. 12, 8-11.Google Scholar
Templeton, B., (1964). The Fruits and Seeds of the Rancho La Brea Pleistocene Deposits. Ph.D. Thesis. Oregon State Univ, Corvallis, Oregon, Also.Google Scholar
Templeton, B., Dissertation Abstracts. Order No. 64-13,378.Google Scholar
Trewartha, G.T., (1966) The Earth's Problem Climates. Methuen, London. Google Scholar
Troxell, H.C., (1954) Hydrology of the San Bernardino and Eastern San Gabriel Mountains, California. Department of the Interior, U. S. Geological Survey Hydrologic Investigations Atlas HA-1.Google Scholar
Troxell, H.C., Hofmann, W., (1954). Hydrology of the Los Angeles region. Jahns, R.H., Geology of Southern California. Bulletin 170. Vol. I, 5-12 (Chapter VI).Google Scholar
Valentine, J.W., (1961). Paleoecologic molluscan geography of the Californian Pleistocene. University of California Publications in the Geological Sciences. 34, 309-442.Google Scholar
Valentine, J.W., Meade, R.F., (1961). Californian Pleistocene paleotemperatures. University of California Publications in the Geological Sciences. 40, 1-46.Google Scholar
Valentine, J.W., Emerson, W.K., (1961). Environmental interpretation of Pleistocene marine species—a discussion. Journal of Geology. 69, 616-618.Google Scholar
Valentine, J.W., Lipps, J.H., (1967). Late Cenozoic history of the Southern California Islands. Philbrick, R.N., Proceedings of the symposium on the Biology of the California Islands. Santa Barbara Botanic Garden, Santa Barbara, 21-35.Google Scholar
Van Devender, T.R., (1976). The biota of the hot deserts of North America during the last glaciation: the packrat midden record. Abstracts, American Quaternary Association, Fourth Biennial Meeting. Tucson 62-67.Google Scholar
Van Devender, T.R., Mead, J.I., (1976). Late Pleistocene and modern plant communities of Shinumo Creek and Peach Springs Wash, Lower Grand Canyon, Arizona. Journal of the Arizona Academy of Sciences. 11, 16-22.Google Scholar
Warter, J.K., (1976). Late Pleistocene plant communities—evidence from the Rancho La Brea tar pits. Latting, J., Plant Communities of Southern California. California Native Plant Society Special Publication No. 2. 32-39 Berkeley.Google Scholar
Wells, P.48., Berger, R., (1967). Late Pleistocene history of coniferous woodland in the Mojave Desert. Science. 155, 1640-1647.Google Scholar
Wendland, W.M., Bryson, R.A., (1974). Dating climatic episodes of the Holocene. Quaternary Research. 4, 9-24.Google Scholar
Williams, J., Higginson, J.J., Rohrbough, J.D., (1973). Ocean surface currents. Pirie, R.G., Oceanography; Contemporary Readings in Ocean Sciences. Oxford Univ. Press, London, 99-107.Google Scholar