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Paleoecologic, paleoclimatic, and evolutionary significance of the Oligocene Creede flora, Colorado

Published online by Cambridge University Press:  08 April 2016

Jack A. Wolfe  and
Howard E. Schorn
Jack A. Wolfe
Affiliation:
Paleontology and Stratigraphy Branch, U.S. Geological Survey, Denver, Colorado 80225
Howard E. Schorn
Affiliation:
Schorn. Museum of Paleontology, University of California, Berkeley, California 94720
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Abstract

Application of multivariate statistical techniques, especially correspondence analysis, results in the recognition of four major communities for the Creede plant assemblages: fir-spruce forest, fir-pine forest, pine-juniper forest or woodland, and mountain mahogany chaparral. Physiognomy of the Creede assemblages indicates a mean annual temperature of <2.5°C. Paleoaltitudinal estimates based on this temperature estimate are inconsistent with physiographic and structural data of post-depositional uplift, unless the climatic effects of a closed basin are factored in; these effects imply that the Creede paleotemperature (and hence paleoaltitude) is applicable to the caldera rim. A variety of data indicate that summers were dry and most precipitation occurred as snow. The stratigraphic sequence of assemblages indicates that significant precipitational change occurred during deposition of the Creede plant-bearing beds. Chamaebatiaria, a shrub that now inhabits dry, open environments, had an ancestral taxon characteristic of the Creede fir-forest communities and strongly indicates a major shift in habitat for this lineage during the Neogene. A second genus, Luetkea, which is now herbaceous, is represented by a probable woody ancestral taxon that was common in the Creede forest communities. Consideration of the adaptive and morphologic histories of the Creede lineages suggests that physiologic adaptation may precede morphologic change. The Creede forest communities have no modern homologues.

Type
Articles
Information
Paleobiology , Volume 15 , Issue 2 , Spring 1989 , pp. 180 - 198
Copyright
Copyright © The Paleontological Society 

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References

Literature Cited

Axelrod, D. I. 1966. A method of determining the altitudes of Tertiary floras. Paleobotanist 14:144171.Google Scholar
Axelrod, D. I. 1987. The late Oligocene Creede flora, Colorado. University of California Publications in Geological Sciences 130:1235.Google Scholar
Becker, H. F. 1961. Oligocene plants from the upper Ruby River Basin, southwestern Montana. Geological Society of America Memoir 82.Google Scholar
Bencrezi, J. P. 1973. L'Analyse des Donnees. 2, L'Analyse des Correspondences. Dunod; Paris.Google Scholar
Burnham, R. J., and Spicer, R. A. 1986. Forest litter preserved by volcanic activity at El Chichon, Mexico: a potentially accurate record of the pre-eruption vegetation. Palaios 1:158161.Google Scholar
Cronquist, A. 1981. An Integrated System of Classification of Flowering Plants. Columbia University Press; New York.Google Scholar
Ferlatte, W. J. 1974. Flora of the Trinity Alps of Northern California. University of California Press; Berkeley.Google Scholar
Fowells, H. A. 1965. Silvics of forest trees of the United States. U.S. Department of Agriculture Handbook 271.Google Scholar
Franklin, J. F., and Dyrness, C. T. 1969. Vegetation of Oregon and Washington. U.S. Forest Service Research Paper PSW-80.Google Scholar
Griffin, J. R., and Critchfield, W. B. 1972. The distribution of forest trees in California. U.S. Forest Service Research Paper PSW-82/1972.Google Scholar
Hill, M. O. 1973. Reciprocal averaging: an eigenvector method of ordination. Journal of Ecology 61:237249.Google Scholar
Hill, M. O. 1979. Correspondence analysis: a neglected multivariate method. Applied Statistics 23:340354.Google Scholar
Hill, M. O., and Gauch, H. D. 1980. Detrended correspondence analysis: an improved ordination technique. Vegetatio 42:4758.Google Scholar
MacGinitie, H. D. 1953. Fossil plants of the Florissant beds, Colorado. Carnegie Institution of Washington Publication 599.Google Scholar
Meyer, H. W. 1986. An Evaluation of the Methods for Estimating Paleoaltitudes Using Tertiary Floras from the Rio Grande Rift Vicinity, New Mexico and Colorado. Unpublished Ph.D. dissertation, University of California at Berkeley. Berkeley, California.Google Scholar
Muller, J. 1981. Fossil pollen records of extant angiosperms. Botanical Review 47:1142.Google Scholar
Munz, P. A., and Keck, D. D. 1959. A California Flora. University of California Press; Berkeley.Google Scholar
Schorn, H. E., and Wolfe, J. A. 1989. Taxonomic revision of the Spermatopsida of the Oligocene Creede flora, southern Colorado. U.S. Geological Survey Open-File Report.Google Scholar
Spicer, R. A.In press. The formation and interpretation of plant megafossil assemblages. In Callow, J. (ed.), Advances in Botanical Research. Academic Press; New York.Google Scholar
Spicer, R. A., and Wolfe, J. A. 1987. Plant taphonomy of late Holocene deposits in Trinity (Clair Engle) Lake, northern California. Paleobiology 13:227245.CrossRefGoogle Scholar
Spicer, R. A., Wolfe, J. A., and Nichols, D. J. 1987. Alaskan Cretaceous-Tertiary floras and Arctic origins. Paleobiology 13:7383.Google Scholar
Steven, T. A., and Eaton, G. P. 1975. Environment of ore deposition in the Creede mining district, San Juan Mountains, Colorado: I. Geologic, hydrologic, and geophysical setting. Economic Geology 70:10231037.Google Scholar
Steven, T. A., and Ratte, J. C. 1965. Geology and structural control of ore depostion in the Creede district, San Juan Mountains, Colorado. U.S. Geological Survey Professional Paper 487.Google Scholar
Taggart, R. W., and Cross, A. T. 1980. Vegetation change in the Miocene Succor Creek flora of Oregon and Idaho: a case study in paleosuccession. Pp. 185210. In Dilcher, D. L., and Taylor, T. N. (eds.), Biostratigraphy of Fossil Plants. Dowden, Hutchinson, and Ross; Stroudsburg, Pennsylvania.Google Scholar
Tiffney, B. H. 1985. Seed size, dispersal syndromes, and the rise of the angiosperms: evidence and hypothesis. Annals of the Missouri Botanical Garden 7:551576.Google Scholar
Wolfe, J. A. 1971. Tertiary climatic fluctuations and methods of analysis of Tertiary floras. Palaeogeography, Palaeoclimatology, and Palaeoecology 9:2757.Google Scholar
Wolfe, J. A. 1979. Temperature parameters of the humid to mesic forests of eastern Asia and their relation to forests of other regions of the Northern Hemisphere and Australasia. U.S. Geological Survey Professional Paper 1106.CrossRefGoogle Scholar
Wolfe, J. A. 1981. Paleoclimatic significance of the Oligocene and Neogene floras of northwestern United States. Pp. 79101. In Niklas, K. J. (ed.), Paleobotany, Paleoecology, and Evolution, Volume 2. Praeger Publishers; New York.Google Scholar
Wolfe, J. A. 1988. An overview of the origins of the modern flora and vegetation of the northern Rocky Mountains. Annals of the Missouri Botanical Garden 74:785803.Google Scholar
Wolfe, J. A., and Upchurch, G. R. Jr. 1987. North American nonmarine climates during the Late Cretaceous. Palaeogeography, Palaeoclimatology, and Palaeoecology 61:3377.CrossRefGoogle Scholar
Wolfe, J. A., and Wehr, W. 1987. Middle Eocene dicotyledonous plants from Republic, northeastern Washington. U.S. Geological Survey Bulletin 1597.Google Scholar
Wolfe, J. A., and Wehr, W. 1988. Rosaceous Chamaebatiaria-like foliage from the Paleogene of western North America. Aliso 12:177200.Google Scholar