Hostname: page-component-cd9895bd7-fscjk Total loading time: 0 Render date: 2024-12-26T19:49:18.319Z Has data issue: false hasContentIssue false

Potential of Opal Phytoliths for use in Paleoecological Reconstruction

Published online by Cambridge University Press:  20 January 2017

Irwin Rovner*
Affiliation:
Department of Anthropology, University of Wisconsin, Madison, Wisconsin 53206 USA

Abstract

Opal phytoliths, inorganic biogenetic plant particles of microscopic size, were investigated to determine the level at which their varied morphology is taxonomically significant. Extraction methods for the isolation of these particles from living plants and from soils were developed to provide maximum preservation of morphological features while remaining simple, rapid, and inexpensive. Extracts were made and microscopically viewed from 30 live specimens, of which 16 were systematically typed in order to develop taxonomic guidelines for their identification in soils. Clear taxonomic differentiation was noted between and within major plant groups with considerable indication that more detailed investigation will yield finer subdivisions. Since opal phytoliths are reported to be a particularly durable fossil found in deposits as far back as Tertiary Age, it appears that opal phytolith analysis can provide paleobotanical information comparable to palynological data in many areas where pollen is absent. When used in conjunction with pollen where present, they should serve to confirm pollen data as well as provide additional botanical data not available in pollen studies.

Type
Original Articles
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.)

References

Baker, George (1959a). Opal phytoliths in some Victorian soils and “Red Rain residues”. Australian Journal of Botany 1, 6487.Google Scholar
Baker, George (1959). A contrast in the opal phytolith assemblages of two Victorian soils. Australian Journal of Botany 7, 8896.CrossRefGoogle Scholar
Baker, George (1959). Fossil opal-phytoliths and phytolith nomenclature. Australian Journal of Science 21, 305306.Google Scholar
Baker, George (1961). Opal phytoliths from sugar cane, San Fernando, Philippine Islands. Memoirs of the Queensland Museum 14, 112.Google Scholar
Baker, George, Jones, L.H.P., and Wardrop, I.D. (1961). Opal phytolith and mineral particles in the rumen of the sheep. Australian Journal of Agricultural Research 12, 462471.Google Scholar
Beavers, A.H., and Stephen, I. (1958). Some features of the distribution of plant-opal in Illinois soils. Soil Science 86.CrossRefGoogle Scholar
Brydon, James E., Dore, William G., and Clark, John S. (1963). Silicified plant astroscereids preserved in soil. Proceedings of the Soil Science Society of America 27, 476477.CrossRefGoogle Scholar
Jones, L.H.P., and Milne, A.A. (1963). Studies of silica in the oat plant, I. Plant and Soil 18, No. 2.Google Scholar
Jones, L.H.P., Milne, A.A., and Wadham, S.M. (1963). Studies of silica in the oat plant, II. Plant and Soil 18, 3.CrossRefGoogle Scholar
Jones, Robert L. (1964). Note on occurrence of opal phytoliths in some Cenozoic sedimentary rocks. Journal of Paleontology 38, 773775.Google Scholar
Jones, Robert L., and Beavers, A.H. (1963). Some mineralogical and chemical properties of plant opal. Soil science 96, 6.CrossRefGoogle Scholar
Jones, Robert L., and Beavers, A.H. (1964a). Variation of opal phytolith content among some great soil groups in Illinois. Proceedings of the Soil Science Society of America 28, No. 5.Google Scholar
Jones, Robert L., and Beavers, A.H. (1964). Aspects of caternary and depth distribution of opal phytoliths in Illinois soils. Proceedings of the Soil Science Society of America 28, 3.CrossRefGoogle Scholar
Lanning, F. C. (1960). Nature and distribution of silica in strawberry plants. Proceedings of the American Horticultural Society 76, 349358.Google Scholar
Lanning, F.C. (1961). Silica and calcium in black raspberries. Proceedings of the American Horticultural Society 76, 367371.Google Scholar
Lanning, F.C., Ponnaiya, R.W.X., and Crumpton, C.F. (1958). The chemical nature of silica in plants. Plant Physiology 33, 339343.Google Scholar
Netolitzky, Fritz (1929). Die kieselkorper. Linsbauers Handbuch der Pflanzenanatomie 25, No. 3.Google Scholar
Parry, D.Wynn, Smithson, Frank (1958a). Silicification of bulliform cells in grasses. Nature 181, 15491550.CrossRefGoogle Scholar
Parry, D.Wynn, and Smithson, Frank (1958). Silicification of branched cells in the leaves of Nardusstricta L. Nature 182, 14601461.CrossRefGoogle Scholar
Pease, Douglas S. (1967). Opal Phytoliths as Indicators of Paleosols. M.Sc. thesis, New Mexico State University. University Park, N.M.Google Scholar
Smithson, Frank (1958). Grass opal in British soils. Journal of Soil Science 9, No. 1.Google Scholar
Twiss, P.C., Suess, Erwin, and Smith, R.M. (1969). Morphological classification of grass phytoliths. Proceedings of the Soil Science Society of America 33, No. 1.Google Scholar
Wilding, L.P. (1967). Radiocarbon dating of biogenetic opal. Science 156, 6667.Google Scholar
Wilding, L.P., and Drees, L.R. (1968). Biogenic opal in soils as an index of vegetative history in the prairie peninsula. In “The Quaternary of Illinois, (Bergstrom, R.E. ed), pp. 96103. University of Illinois College of Agriculture Special Publication 14 Urbana, Illinois.Google Scholar
Witty, John E., and Knox, Ellis G. (1964). Grass opal in some chestnut and forested soils of north central Oregon. Proceedings of the Soil Science Society of America 28, No. 5.Google Scholar