Hostname: page-component-78c5997874-8bhkd Total loading time: 0 Render date: 2024-11-06T13:51:42.698Z Has data issue: false hasContentIssue false

The Dynamic Nature of Holocene Vegetation A Problem in Paleoclimatology, Biogeography, and Stratigraphic Nomenclature1

Published online by Cambridge University Press:  20 January 2017

H.E. Wright Jr.*
Affiliation:
Limnological Research Center, University of Minnesota, Minneapolis, Minnesota 55455 USA

Abstract

For more than a century it has been postulated that the Holocene vegetation of western Europe has changed in significant ways. A half-century ago a lively debate revolved on whether there were one or two dry intervals causing bogs to dry out and become forested, or whether instead the climate warmed to a maximum and then cooled. Today none of these climatic schemes is accepted without reservation, because two nonclimatic factors are recognized as significant: the differential immigration rates of dominant tree types (e.g., spruce in the north and beech in the south) brought unexpected changes in forest composition, and Neolithic man cleared the forest for agriculture and thereby disrupted the natural plant associations.

In North America some of the same problems exist. In the hardwood forests of the Northeast, which are richer than but otherwise not unlike those of western Europe, the successive spread of white pine, hemlock, beech, hickory, and chestnut into oakdominated forests provides a pollen sequence that may yield no climatic message. On the other hand, on the ecotone between these hardwood forests and the conifer forests of the Great Lakes-St. Lawrence area, the southward expansion of spruce, fir, and tamarack in the late Holocene implies a climatic cooling of regional importance, although the progressive conversion of lakes to wetlands favored the expansion of wetland forms of these genera.

In the southeastern states the late-Holocene expansion of southern pines has uncertain climatic significance. About all that can be said about the distribution and ecology of the 10 or so species is that some of them favor sandy soils and are adapted to frequent fires. In coastal areas the expansion of pines was accompanied by development of great swamps like Okefenokee and the Everglades—perhaps related to the stabilization of the water table after the early Holocene rise of sea level. The vegetation replaced by the pines in Florida consisted of oak scrub with prairie-like openings, indicating dry early Holocene conditions, which in fact had also prevailed during the time of Wisconsin glaciation.

In the Midwest the vegetation history provides a clearer record of Holocene climatic change, at least along the prairie border in Minnesota. With the withdrawal of the boreal spruce forest soon after ice retreat, pine forest and hardwood forest succeeded rapidly, as in the eastern states. But prairie was not far behind. By 7000 years ago the prairie had advanced into east-central Minnesota, 75 miles east of its present limit. It then withdrew to the west, as hardwoods expanded again, followed by conifers from the north. The sequence easily fits the paleoclimatic concept of gradual warming and drying to a maximum, followed by cooling to the present day. It is supported by independent fossil evidence from lake sediments, showing that lakes were shallow or even intermittently dry during mid-Holocene time.

Here we have a paleoclimatic pattern that is consistent with the record from glaciers in the western mountains—a record that involves a late-Holocene Neoglaciation after a mid-Holocene interval of distant glacial recession. Just as the Neoglaciation is time-transgressive, according to the review of its evidence by Porter and Denton, so also is the mid-Holocene episode of maximum warmth, and they are thus both geologicclimate units. The warm episode is commonly termed the Hypsithermal, which, however, was defined by Deevey and Flint as a time-stratigraphic unit that is supposed to have time-parallel rather than time-transgressive boundaries. It was defined on the basis of pollen-zone boundaries in western Europe and the northeastern United States that have a sound biogeographic but questionable paleoclimatic basis. Perhaps it should be redefined as Porter and Denton suggest, as a geologic-climate unit with recognizable time-transgressive boundaries that match the gradual geographic shifts in the general circulation of the atmosphere and the resulting location of storm tracks and weather patterns. Holocene glacial and vegetational progressions provide a good record of climatic change, if one can work out the lag effects related to the glacial economy and the geographic factors controlling tree migration. The terminology for the Holocene, where so much time control is available, should indicate the dynamic character not only of the climate but also of the geologic and biogeographic processes controlled by climate.

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

Contribution 148, Limnological Research Center, University of Minnesota.

References

Amundson, D.H., (1974). The early postglacial transition from spruce forest to pine forest in Minnesota. M.S. Thesis University of Minnesota.Google Scholar
Andersson, J.G., (1910). Die Veränderungen des Klimas seit dem Maximum der letzten Eiszeit. 11th International Geological Congress (Stockholm, 1910) .Google Scholar
Ashley, G.H., (1933). Classification and nomenclature of rock units. Geological Society of America Bulletin 44 423459(See revisions as Code of Stratigraphic Nomenclature, 1970, American Association of Petroleum Geologists).CrossRefGoogle Scholar
Baker, R.G., (1970). Pollen sequence from late Quaternary sediments in Yellowstone Park. Science 168 14491450.CrossRefGoogle ScholarPubMed
Bright, R.C., (1968). Surface-water chemistry of some Minnesota lakes, with preliminary notes on the diatoms. University of Minnesota, Limnological Research Center, Interim Report 3 .Google Scholar
Bryson, R.A., Baerreis, D.A., Wendland, W.M., (1970). The character of late-glacial and post-glacial climatic changes. Dort, Wakefield Jr., Jones, J.Knox Jr., Pleistocene and Recent Environments of the Central Great Plains. University of Kansas Press Lawrence 5376.Google Scholar
Cooper, W.S., (1958). Terminology of postValders time. Geological Society of America Bulletin 69 941945.CrossRefGoogle Scholar
Davis, M.B., (1965). Phytogeography and palynology of northeastern United States. Wright, H.E. Jr., Frey, David G., The Quaternary of the United States Princeton University Press Princeton, NJ 377401.Google Scholar
Davis, M.B., (1967). Pollen accumulation rates at Rogers Lake, Connecticut, during late-and postglacial time. Review of Palaeobotany and Palynology 2 219230.Google Scholar
Davis, M.B., (1976). Pleistocene biogeography of temperate deciduous forests. Geoscience and Man 13 Louisiana State University 1326.Google Scholar
Deevey, E.S. Jr., (1943). Additional pollen diagrams from southern New England. American Journal of Science 241 717752.CrossRefGoogle Scholar
Deevey, E.S. Jr., (1948). Biogeography of the Pleistocene. Geological Society of America Bulletin 60 13151416.CrossRefGoogle Scholar
Deevey, E.S. Jr., (1969). Coaxing history to conduct experiments. BioScience 19 4043.CrossRefGoogle Scholar
Deevey, E.S. Jr., Flint, R.F., (1957). Postglacial hypsithermal interval. Science 125 182184.CrossRefGoogle ScholarPubMed
Fries, M., (1962). Pollen profiles of late Pleistocene and Recent sediments from Weber Lake, Minnesota. Ecology 43 295308.CrossRefGoogle Scholar
Grüger, E., (1972). Late Quaternary vegetation development in south-central Illinois. Quaternary Research 2 217231.Google Scholar
Hansen, B.S., Easterbrook, D.J., (1974). Stratigraphy and palynology of late Quaternary sediment in Puget lowland, Washington. Geological Society of America Bulletin 85 587602.2.0.CO;2>CrossRefGoogle Scholar
Haworth, E.Y., (1972). Diatom succession in a core from Pickerel Lake, northeastern South Dakota. Geological Society of America Bulletin 83 157172.CrossRefGoogle Scholar
Heusser, C.J., (1965). A Pleistocene phytogeographical sketch of the Pacific Northwest and Alaska. Wright, H.E. Jr., Frey, David G., The Quaternary of the United States Princeton University Press Princeton, NJ 469484.Google Scholar
Heusser, C.J., (1973). Environmental sequence following Fraser advance of the Juan de Fuca lobe, Washington. Quaternary Research 3 284306.CrossRefGoogle Scholar
Iversen, J., (1941). Land occupation in Denmark's stone age. Danmarks Geologiske Undersøgelse Ser. 2 No. 66 .Google Scholar
Iversen, J., (1969). Retrogressive development of a forest ecosystem demonstrated by pollen diagrams from fossil mor. Oikos Supplement 12 3549.Google Scholar
Iversen, J., (1973). The development of Denmark's nature since the last glacial. Danmarks Geologiske Undersøgelse, Ser. 5 No. 7-C .Google Scholar
Jacobson, G.L., (1975). A palynological study of the history and ecology of white pine in Minnesota. University of Minnesota Ph.D. Thesis .Google Scholar
Likens, G.E., Davis, M.B., (1975). Postglacial history of Mirror Lake and its watershed in New Hampshire, U.S.A.: An initial report. Proceedings of the 19th International Limnological Congress Winnipeg 1974 982993.Google Scholar
McAndrews, J.H., (1966). Postglacial history of prairie, savanna, and forest in northwestern Minnesota. Torrey Botanical Club, Mem. 22 No. 2 .Google Scholar
Maher, L.J. Jr., (1972). Absolute pollen diagram of Redrock Lake, Boulder County, Colorado. Quaternary Research 2 531553.CrossRefGoogle Scholar
Miller, N.G., (1973). Late-glacial and postglacial vegetation change in southwestern New York State. New York State Museum and Science Service Bulletin 420 .Google Scholar
Porter, S.C., Denton, G.H., (1967). Chronology of neoglaciation in the North American Cordillera. American Journal of Science 265 177210.Google Scholar
Sears, P.B., (1935). Glacial and postglacial vegetation. Botanical Review 1 3751.CrossRefGoogle Scholar
Sears, P.B., (1942). Xerothermic theory. Botanical Review 8 708736.CrossRefGoogle Scholar
Stuiver, M., (1970). Oxygen and carbon isotope ratios of freshwater carbonates as climatic indicators. Journal of Geophysical Research 75 52475257.Google Scholar
Terasmae, J., Anderson, T.W., (1970). Hypsithermal range extension of white pine (Pinus strobus L.) in Quebec, Canada. Canadian Journal of Earth Sciences 7 406413.CrossRefGoogle Scholar
Von Post, L., (1930). Problems and working lines in the post-Arctic forest history of Europe. Report of the Proceedings of the International Botanical Congress Copenhagen, 1930.Google Scholar
Von Post, L., (1946). The prospect for pollen analysis in the study of the Earth's climatic history. New Phytologist 45 193217.CrossRefGoogle Scholar
Waddington, J.C.B., Wright, H.E. Jr., (1974). Late Quaternary vegetational changes on the east side of Yellowstone Park, Wyoming. Quaternary Research 4 175184.CrossRefGoogle Scholar
Watts, W.A., (1973). Rates of change and stability in vegetation in the perspective of long periods of time. Birks, H.J.B., West, R.G., Quaternary Plant Ecology Blackwell Oxford 194206.Google Scholar
Watts, W.A., 1976a. The Quaternary vegetation history of the southeastern United States. Appalachian Geobotany. Proceedings of the 1973 International Geobotany Conference University of Tennessee Press.Google Scholar
Watts, W.A., 1976b. A late Quaternary record of vegetation from Lake Annie, southcentral Florida. Geology 3 344346.2.0.CO;2>CrossRefGoogle Scholar
Watts, W.A., Bright, R.C., (1968). Pollen, seed, and mollusk analysis of a sediment core from Pickerel Lake, northeastern South Dakota. Geological Society America Bulletin 79 855876.Google Scholar
Watts, W.A., Winter, T.C., (1966). Plant macrofossils from Kirchner Marsh, Minnesota—A paleoecological study. Geological Society of America Bulletin 77 13391359.CrossRefGoogle Scholar
Wendland, W.M., Bryson, R.A., (1974). Dating climatic episodes of the Holocene. Quaternary Research 4 924.Google Scholar
Wright, H.E. Jr., 1968a. History of the prairie peninsula Dort, Wakefield Jr., Jones, J.Knox Jr., Pleistocene and Recent Environments of the Central Great Plains University of Kansas Press Lawrence 7888.Google Scholar
Wright, H.E. Jr., 1968b. The roles of pine and spruce in the forest history of Minnesota and adjacent areas. Ecology 49 937955.CrossRefGoogle Scholar
Wright, H.E. Jr., Watts, W.A., (1969). Glacial and vegetational history of northeastern Minnesota. Minnesota Geological Survey Special Publication 11 .Google Scholar
Wright, H.E. Jr., Winter, T.C., Patten, H.L., (1963). Two pollen diagrams from southeastern Minnesota: Problems in the regional late-glacial and postglacial vegetational history. Geological Society of America Bulletin 74 13711396.CrossRefGoogle Scholar