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Pollen and Archaeology at Wetherill Mesa1

Published online by Cambridge University Press:  27 June 2018

Paul S. Martin  and
William Byers
Paul S. Martin
Affiliation:
Geochronology Laboratories, University of Arizona, Tucson, Arizona
William Byers
Affiliation:
Geochronology Laboratories, University of Arizona, Tucson, Arizona
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Abstract

Nine profiles of prehistoric cultural deposits at Wetherill Mesa, Mesa Verde National Park, Colorado, were analyzed for fossil pollen content. Relatively large numbers of corn (Zea) pollen occur in certain deposits of Mug House. In the alluvium retained behind low walls of two check-dams, the frequency of Zea is relatively low (.07%) but approximates the frequency of Zea pollen in soil of a garden on Chapin Mesa planted in Indian corn since 1919. Evidently, soil behind the prehistoric checkdams served as corn plots. The abundance of pollen resembling bee-weed (Cleome serrulata) suggests a more important role for the caper family in prehistoric time than would be inferred from its macrofossil record alone. The Cieome-type is common in prehistoric refuse and in human coprolite in the Four Corners area.

Pollen content of matrix within a single archaeological site may vary, depending on the nature of the deposit. Although parts of their deposits overlap in time, the pollen content of (1) a trash slope, (2) a kiva, and (3) a work area within Mug House pueblo varies greatly, especially in economic pollen. Variation between profiles is reduced considerably when they are taken from the same type of deposit, that is, adjacent kivas or trash profiles.

The hope that the fossil record would shed new light on the cause of abandonment of Mesa Verde was largely unrealized. The main stratigraphic event in the pollen sequence of the last 1000 years is a relative increase in juniper and pine pollen following abandonment 700 years ago. Ecologically, this rise can be explained as the result of secondary plant succession with first juniper and then pinyon invading fields when human disturbance ended. It may or may not reflect climatic change.

Type
3 The Natural Sciences
Information
Memoirs of the Society for American Archaeology , Volume 19: Contributions of the Wetherill Mesa Archeological Project , October 1965 , pp. 122 - 135
Copyright
Copyright © Society for American Archaeology 1965 

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Footnotes

1

This is Contribution No. 6 of the Wetherill Mesa Archeological Project and Contribution No. 78, Program in Geochronology, University of Arizona.

References

Davis, M. B. 1963 On the Theory of Pollen Analysis. American Journal of Science, Vol. 261, pp. 897912.Google Scholar
Elmore, F. H. 1944 Ethnobotany of the Navajo. The University of New Mexico Bulletin with the School of American Research, No. 392. Monograph series, Vol. 1, No. 7. University of New Mexico Press, Albuquerque.Google Scholar
Franke, P. R. and Watson, D. 1936 An Experimental Corn Field in Mesa Verde National Park. Symposium on Prehistoric Agriculture, The University of New Mexico Bulletin No. 296, pp. 3541. University of New Mexico Press, Albuquerque.Google Scholar
Funkhouser, J. W. and Evitt, W. R. 1959 Preparation Techniques for Acid-insoluble Microfossils. Micropaleontology, Vol. 5, No. 3, New York.Google Scholar
Hayes, A. C. 1964 The Archeological Survey of Wetherill Mesa, Mesa Verde National Park. National Park Service, Archeological Series (in press). Washington.Google Scholar
Hevly, R. H. 1964 Pollen Analysis of Quaternary Archeological and Lacustrine Sediments from the Colorado Plateau. Doctoral dissertation, University of Arizona, Tucson.Google Scholar
Hoffmeister, W. S. 1960 Sodium Hypochlorite, A New Oxidizing Agent for the Preparation of Microfossils. Oklahoma Geology Notes, Vol. 20, No. 2, pp. 34–5. Norman.Google Scholar
Leopold, L. B., Leopold, E. B., and Wendorf, F. 1963 Some Climatic Indicators in the Period A.D. 1200-1400 in New Mexico. Proceedings of the Rome Symposium Organized by UNESCO and WMO, pp. 265–70. UNESCO, Paris.Google Scholar
Martin, P. S. 1963 The Last 10,000 Years: A Fossil Pollen Record of the American Southwest. University of Arizona Press, Tucson.Google Scholar
Martin, P. S. and Sharrock, F. W. 1964 Pollen Analysis of Prehistoric Human Feces: A New Approach to Ethnobotany. American Antiquity, Vol. 30, No. 2, pp. 168–80. Salt Lake City.Google Scholar
Rohn, A. H. 1963 Prehistoric Soil and Water Conservation on Chapin Mesa, Southwestern Colorado. American Antiquity, Vol. 28, No. 4, pp. 441–55. Salt Lake City.Google Scholar
Schoenwetter, J. and Eddy, F. W. 1964 Alluvial and Palynological Reconstruction of Environments, Navajo Reservoir District. Museum of New Mexico Papers in Anthropology, No. 13. Santa Fe.Google Scholar
Stevenson, M. E. 1915 Ethnobotany of the Zuni Indians. Thirtieth Annual Report of the Bureau of American Ethnology for 1908 and 1909, pp. 31102. Washington, D.C.Google Scholar
Whiting, A. F. 1950 Ethnobotany of the Hopi. Museum of Northern Arizona Bulletin, No. 15. Flagstaff.Google Scholar
Woodbury, A. M. 1947 Distribution of Pigmy Conifers in Utah and Northern Arizona. Ecology, Vol. 28, pp. 113–26. Durham.Google Scholar
Woodbury, R. B. 1961 Prehistoric Agriculture at Point of Pines, Arizona. Memoirs of the Society for American Archaeology, No. 17. Salt Lake City.Google Scholar