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Continuous Holocene Record of Diatom Stratigraphy, Paleohydrology, and Anthropogenic Activity in a Spring-Mound in Southwestern United States

Published online by Cambridge University Press:  20 January 2017

Dean W. Blinn ,
Richard H. Hevly  and
Owen K. Davis
Dean W. Blinn
Affiliation:
Department of Biological Sciences, Northern Arizona University, Flagstaff, Arizona 86011
Richard H. Hevly
Affiliation:
Department of Biological Sciences, Northern Arizona University, Flagstaff, Arizona 86011
Owen K. Davis
Affiliation:
Department of Geosciences, University of Arizona, Tucson, Arizona 85721
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Abstract

This study presents the first continuous record of fossil diatoms taken from an open spring-mound in southwestern United States. Diatoms were analyzed from a radiocarbon-dated core taken from Montezuma Well, a near thermally constant spring in northcentral Arizona. Fluctuations in total diatom density, oscillations in the relative abundance of Anomoeoneis sphaerophora, and intermittent deposition of calcite suggest that water levels in Montezuma Well underwent dramatic fluctuations to the degree of being intermittently dry, or at least very shallow, during the middle Holocene (∼8000-5000 yr B.P.). The fluctuations in water level probably correspond to oscillations in regional temperature and precipitation, which regulate hydrologic input and evaporation rates. The dramatic fluctuations in water level during the middle Holocene suggest that the endemic biota of Montezuma Well underwent relatively rapid speciation within the past ∼5000 yr. The appearance of endemic species (Gomphonema montezumense and Cyclotella pseudostelligera f. parva ) at ∼5000-3000 yr B.P. supports this hypothesis. Diatom indicators for organic enrichment (Aulacoseira granulata and A. islandica) closely coincide with the prehistoric native occupation of Montezuma Well.

Type
Research Article
Information
Quaternary Research , Volume 42 , Issue 2 , September 1994 , pp. 197 - 205
Copyright
University of Washington

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References

American Public Health Association. (1975). “Standard Methods for the Examination of Water and Wastewater,” 14th ed. APHA, Washington, DC.Google Scholar
Anderson, R, S. (1993). A 35,000 year vegetation and climate history from Potato Lake, Mogollon Rim, Arizona. Quaternary Research 40, 351359.Google Scholar
Avery, C. C., and Helmke, M. (1993). “Montezuma Well: A Dynamic Hydrologic System.” National Park Service Symposium, Flagstaff, AZ.Google Scholar
Bahls, L. L. Weber, E. E., and Jarvie, J. O. (1984). Ecology and distribution of major diatom ecotypes in the southern Fort Union Coal Region of Montana. Geological Survey Professional Paper 1289, 1151.Google Scholar
Batchelder, G. L., and Cole, G. A. (1978). “Evidence of Post-pluvial Water Level Fluctuation at Montezuma Well, Coconino County, Arizona, U.S.A.” Report to National Park Service. U.S. Department of Interior.Google Scholar
Betancourt, J. L. Van Devender, T. R., and Martin, P. S. (1990). Synthesis and prospectus. In “Packrat Middens. The Last 40,000 Years of Biotic Change” (Betancourt, J. L. Van Devender, T. R., and Martin, P. S., Eds.), pp. 435437. Univ. of Arizona Press, Thcson.Google Scholar
Blinn, D. W. (1993). Diatom community structure along physicochemical gradients in saline lakes. Ecology 74, 12461263.CrossRefGoogle Scholar
Blinn, D. W., and Davies, R. W. (1989). The evolutionary importance of mechanoreception in three erpobdellid leech species. Oecologia 79, 69.Google Scholar
Blinn, D. W., and Davies, R. W. (1990). Concomitant diel vertical migration of a predatory leech and its amphipod prey. Freshwater Bi-ology 24, 401407.Google Scholar
Blinn, D. W. Dehdashti, B. Runck, C., and Davies, R. W. (1990). The importance of prey size and density in an endemic predator-prey couple (leech Erpobdella monfezwma-amphipod Hyalella montezuma). Journal of Animal Ecology 59, 187192.Google Scholar
Boucher, P. (1980). “The Phytoplankton Ecology of Montezuma Well, Arizona.” M.Sc. thesis, Northern Arizona University, Flagstaff, AZ.Google Scholar
Boucher, P. Blinn, D. W., and Johnson, D. B. (1984). Phytoplankton ecology in an unusually stable environment (Montezuma Well, Arizona, U.S.A.). Hydrobiologia 119, 149160.Google Scholar
Bradbury, J. P. (1975). Diatom stratigraphy and human settlement in Minnesota. Geological Society of America Special Paper 171, 174.Google Scholar
Bradbury, J. P., and Dean, W. E. (1993). Holocene climatic and limnologic history of the north-central United States as recorded in the varved sediments of Elk Lake, Minnesota: A synthesis. In “Holocene Diatom Paleolimnology of Elk Lake, Minnesota” (Bradbury, J. P. and Dean, W. E., Eds.), Geological Society of America Special Paper 276, pp. 309328.Google Scholar
Bradbury, J. P., and Dieterich-Rurup, K. V. (1993). Holocene diatom paleolimnology of Elk Lake, Minnesota. In “Holocene Diatom Pa-leolimnology of Elk Lake, Minnesota” (Bradbury, J. P. and Dean, W. E., Eds.), Geological Society of America Special Paper 276, pp. 215237.Google Scholar
Bradbury, J. P., and Megard, R. O. (1972). Stratigraphic record of pollution in Shagawa Lake, northeastern Minnesota. Geological Survey of America Bulletin 83, 26392648.Google Scholar
Bradbury, J. P., and Winter, T. C. (1976). Areal distribution and stratigraphy of diatoms in the sediments of Lake Sallie, Minnesota. Ecology 57, 10051014.Google Scholar
Brugam, R. B. (1983). The relationship between fossil diatom assemblages and limnological conditions. Hydrobiologia 98, 223235.Google Scholar
Bryant, V. M. Jr., and Holloway, R. G. (1985). “Pollen Records in Late-Quaternary North American Sediments.” American Association of Stratigraphic Paleontologists Foundation, Hart Graphics, Inc., Austin, TX.Google Scholar
Button, K., and Blinn, D. W. (1975). Planktonic diatom fluctuations in a northern Arizona lake. Southwestern Naturalist 20, 397408.Google Scholar
Cole, G. A. (1983). “A Textbook of Limnology,” 3rd ed. Waveland Press.Google Scholar
Cole, G. A., and Barry, W. T. (1973). Montezuma Well, Arizona as a habitat. Journal of the Arizona Academy of Science 8, 713.Google Scholar
Cole, G. A., and Watkins, R. L. (1977). Hyalella montezuma, a new species (Crustacea: Amphipoda) from Montezuma Well, Arizona. Hydrobiologia 52, 175184.CrossRefGoogle Scholar
Czamecki, D. B. (1979). Epipelic and epilithic diatom assemblages in Montezuma Well National Monument, Arizona. Journal of Phycology 15, 346352.Google Scholar
Czamecki, D. B., and Blinn, D. W. (1979). Observations on southwestern diatoms. II. Caloneis latiuscula var. reimeri n. van, Cyclotella pseudostelligera f. parva n. f., and Gomphonema montezumense n. sp., new taxa from Montezuma Well National Monument. Transactions of the American Microscopical Society 98, 110114.Google Scholar
Davies, R. W. Singhal, R. N„ and Blinn, D. W. (1985). Erpobdella montezuma (Hirudinoidea: Erpobdellidae), a new species of freshwater leech from North America. Canadian Journal of Zoology 63, 965970.Google Scholar
Davis, O. K., and Shafer, D. S. (1992). A Holocene climatic record for the Sonoran Desert from pollen analysis of Montezuma Well, Arizona, USA. Palaeogeography, Palaeoclimatology, and Palaeoecology 92, 107119.Google Scholar
Davis, O. K. Hevly, R. H., and Foust, R. D. Jr., (1985). A comparison of historic and prehistoric vegetation change caused by man in central Arizona. AASP Contribution Series 16, 6376.Google Scholar
Deevey, E. S. Rice, D. G. Rice, P. M. Vaughn, H. H. Brenner, M., and Flannery, M. S. (1979). Mayan urbanism: Impact on a tropical karst environment. Science 206, 298306.Google Scholar
Engstrom, D. Swain, E. B., and Kingston, J. C. (1985). A palaeolimnological record of human disturbance from Harvey’s Lake, Vermont: Geochemistry, pigments, and diatoms. Freshwater Biology 15, 262288.Google Scholar
Hasbargen, J. (1993). “The Paleoenvironment of Stoneman Lake, Arizona.” M.Sc. thesis, Northern Arizona University, Flagstaff, AZ.Google Scholar
Hecky, R. E., and Kilham, P. (1973). Diatoms in alkaline, saline lakes: Ecology and geochemical implications. Limnology and Oceanography 18, 5371.CrossRefGoogle Scholar
Hershler, R., and Landye, J. J. (1988). Arizona Hydrobiidae (Prosobranchia.Rissoacea). Smithsonian Confrt6«fions in Zoology 459, 163.Google Scholar
Hevly, R. H. (1974). Recent paleoenvironments and geological history at Montezuma Well. Journal of the Arizona Academy of Science 9, 6675.Google Scholar
Hevly, R. H. (1985). A 50,000 year record of Quaternary environments; Walker Lake, Coconino Co., Arizona. In “Lake Quaternary Vegeta-tion and Climates of the American Southwest” (Jacobs, B. F. Fall, P. L., and Davis, O. K., Eds.), Contribution Series No. 16, pp. 141154. American Association of Stratigraphic Palynologists.Google Scholar
Hevly, R. H., and Martin, P. S. (1961). Geochronology of pluvial Lake Cochise, southern Arizona. 1. Pollen analysis of shore deposits. Journal of the Arizona Academy of Science 2, 2431.Google Scholar
Hevly, R. H. Nations, J. D., and Szabo, B. J. (1992). “Age and Depositional Environment of TUfa at Montezuma Well and Red Tank Draw, Arizona.” Proceedings of the Southwestern Naturalist Regional Meeting, Tucson, AZ.Google Scholar
Iltis, A. (1974). Phytoplancton des eaux natronees du Kanem (Tchad). VIII. Classification des milieux etudies et especes caracteristiques. Cah. O.R.S.T.O.M. ser. Hydrobiologie. 8, 8191.Google Scholar
Jacobs, B. F. (1983). “Past Vegetation and Climate of the Mogollon Rim Area, Arizona.” Ph.D. thesis, University of Arizona, Tbcson.Google Scholar
King, J. E. (1973). Late Pleistocene palynology and biogeography of the Western Missouri Ozarks. Ecological Monographs 43, 539565.Google Scholar
Lowe, R. (1974). Environmental requirements and pollution tolerance of freshwater diatoms. Environmenfo/Protection Agency, EPA-670/4-74-05. Google Scholar
Mead, J. I. Hevly, R. H., and Agenbroad, L. D. (1990). Late Pleistocene invertebrates and Plant Remains, Mammoth Site, Black Hills, South Dakota. In “Megafauna and Man: Discovery of America’s Heartland” (Agenbroad, L. D. Mead, J. I., and Nelson, L. W., Eds.). The Mammoth Site of Hot Springs, South Dakota, Inc. and Northern Arizona University, Flagstaff, AZ.Google Scholar
Mehringer, P. J. Jr. Martin, P. S., and Haynes, C. V. Jr., (1967). Murray Springs, a mid-Post Glacial pollen record from southern Arizona. American Journal of Science 265, 786797.Google Scholar
Mehringer, P. J. Jr. Schweger, C. E. Wood, W. R., and McMillan, R. B. (1968). Late Pleistocene boreal forest in western Ozark highlands? Ecology 49, 568569.Google Scholar
Nations, J. D. Hevly, R. H. Landye, J. J., and Blinn, D. W. (1982). The paleontology, paleoecology and depositional history of the Miocene-Pliocene Verde Formation, Yavapai County, Arizona. Arizona Geological Society Digest 23, 133149.Google Scholar
Patrick, R., and Reimer, C. W. (1966). “The Diatoms of the United States,” No. 13, Vol. 1. Monographs of the Academy of Natural Sciences of Philadelphia.Google Scholar
Polhemus, J. T. (1976). Notes on North American Nepidae (Hemiptera:Heteroptera). Pan-Pacific Entomology 52, 204208.Google Scholar
Round, F. E. (1981). “The Ecology of Algae.” Cambridge Univ. Press, New York.Google Scholar
Schroeder, A. H., and Hastings, H. F. (1958). “Montezuma Castle National Monument,” National Park Service Historical Handbook Series No. 27. Washington, DC.Google Scholar
Stewart, A., and Blinn, D. W. (1976). Studies on Lake Powell, USA: Environmental factors influencing phytoplankton success in a high desert warm monomictic lake, Archiv fur Hydrobiologe 78, 139164.Google Scholar
van der Werff, A. (1955). A new method of concentrating and cleaning diatoms and other organisms. Verhandlungen der internationalen Vereinigung fur theoretische und angewandte Limnologie 12, 276277.Google Scholar
Watts, W. A. Hansen, B. C. S., and Grimm, E. C. (1992). Camel Lake: A 40,000-yr record of vegetational and forest history from northwestern Florida. Ecology 73, 10561066.Google Scholar
Wright, H. E. Jr. Bent, A. M. Hansen, B. S., and Maher, L. J. Jr., (1973). Present and past vegetation of the Chuska Mountains, northwestern New Mexico. Geological Survey of America Bulletin 84, 11551180.Google Scholar