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Transport Direction of Wisconsinan Loess in Southeastern Minnesota

Published online by Cambridge University Press:  20 January 2017

Joseph A. Mason
Affiliation:
Department of Geography, University of Wisconsin, 550 North Park Street, Madison, Wisconsin 53706
Edward A. Nater
Affiliation:
Department of Soil Science, University of Minnesota
Howard C. Hobbs
Affiliation:
Minnesota Geological Survey

Abstract

A study of Wisconsinan loess in part of southeastern Minnesota confirms earlier suggestions that much of the loess in this region was not derived flora the floodplain of the Mississippi River. Two Wisconsinan loess units, the Peoria Loess and Roxana Silt, occur in the study area. Peoria Loess, 1-8 m thick, fines systematically eastward from an abrupt western border toward the Mississippi. There are no apparent grain-size trends away from other adjacent rivers. Peoria Loess thickness generally decreases eastward, but is highly variable, probably because of differential erosion. Potential sources for this unit are pre-Wisconsinan sediments on the Iowan Erosion Surface immediately west of the border of thick loess and Wisconsinan glacial sources tens or hundreds of kilometers to the west. The underlying Roxana Silt, up to 1 m thick, occurs only near the Mississippi and fines away from that river. The Roxana Silt deposit could reflect aggradation of the Mississippi floodplain because of glacial activity upstream and does not have clear implications for upland vegetation near the study area. By contrast, transport of the Peoria Loess from distant glacial sources or wind erosion of upland surfaces closer to the loess deposit both imply extensive, very sparsely vegetated surfaces west of the study area when the Peoria Loess accumulated.

Type
Articles
Copyright
University of Washington

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References

Baker, R. G. (1992). Full-glacial vegetation in the Upper Midwest. “Abstracts with Programs,” p. 4. North-Central Section, Geological Society of America.Google Scholar
Baker, R. G. Rhodes, R. S. Schwert, D. R Ashworth, A. C. Frest, T. J. Hallberg, G. R., and Janssens, J. A. (1986). A full-glacial biota from southeastern Iowa, U.S.A. Journal of Quaternary Science 1, 91107.CrossRefGoogle Scholar
Baker, R. G. Sullivan, A. E. Hallberg, G. R., and Horton, D. G. (1989). Vegetation changes in western Illinois during the onset of Late Wisconsinan glaciation. Ecology 70, 13631376.CrossRefGoogle Scholar
Bettis, E. A. III, and Kemmis, T. J. (1992). Effects of the last glacial maximum (21,000-16,500 B.P.) on Iowa’s landscapes. “Abstracts with Programs,” p. 5. North-Central Section, Geological Society of America.Google Scholar
Birks, H. J. B. (1976). Late-Wisconsinan vegetational history at Wolf Creek, central Minnesota. Ecological Monographs 46, 395428.CrossRefGoogle Scholar
Calvin, S. (1911). The Iowan drift. Journal of Geology 19, 601602.Google Scholar
Fehrenbacher, J. B. Olson, K. R., and Jansen, I. J. (1986). Loess thickness in Illinois. Soil Science 141, 423431.Google Scholar
Foley, R. L., and Semken, H. A. (1992). Vertebrate biogeography and paleoecology of the last glacial maximum in the Upper Midwest. “Abstracts with Programs.” p. 14. North-Central Section, Geological Society of America.Google Scholar
Foss, J. E., and Rust, R. H. (1962). Soil development in relation to loessial deposition in southeastern Minnesota. Soil Science Society of America Proceedings 26, 270274.CrossRefGoogle Scholar
Frazee, C. J. Fehrenbacher, J. B., and Krumbein, W. C. (1970). Loess distribution from a source. Soil Science Society of America Proceed-ings 34, 296301.CrossRefGoogle Scholar
Garry, C. E. Schwert, D. P. Baker, R. G. Kemmis, T. J. Horton, D. G., and Sullivan, A. E. (1990). Plant and insect remains from the Wisconsinan interstadial/stadial transition at Wedron, north-central Illinois. Quaternary Research 33, 387399.CrossRefGoogle Scholar
Gee, G. W., and Bauder, J. W. (1986). Particle-size analysis. In “Methods of Soil Analysis” (Klute, A., Ed.), Part 1, 2nd ed. pp. 383411. American Society of Agronomy, Madison, WI.Google Scholar
Hallberg, G. R., and Kemmis, T. J. (1986). Stratigraphy and correlations of the glacial deposits of the Des Moines and James lobes and adjacent areas in North Dakota, South Dakota, Minnesota, and Iowa. Quaternary Science Reviews 5, 6568.CrossRefGoogle Scholar
Hallberg, G. R. Fenton, T. E. Miller, G. A., and Lutenegger, A. J. (1978). The Iowan Erosion Surface: An old story, an important lesson, and some new wrinkles. In “Forty-second Annual Tri-State Geological Field Conference Guidebook” (Anderson, R. R., Ed.), pp. 2-22-91. Iowa Geological Survey, Iowa City.Google Scholar
Hanson, B. V. (1976). “The Stratigraphy, Provenance, Age, and Depositional Environment of East Central Iowa Loesses.” Unpublished Ph.D. dissertation, University of Iowa, Iowa City.Google Scholar
Hobbs, H. C., and Goebel, J. E. (1982). “Geologic Map of Minnesota, Quaternary Geology,” Map S-1. Minnesota Geological Survey, Minneapolis.Google Scholar
Hudak, C. M. (1987). “Quaternary Landscape Evolution of the Turkey River Valley, Northeastern Iowa.” Unpublished Ph.D. dissertation, University of Iowa, Iowa City.Google Scholar
Kay, G. F., and Graham, J. B. (1943). The Illinoian and Post-Illinoian geology of Iowa. In “Annual Reports, 1940 and 1941,” pp. 1262. Iowa Geological Survey, Iowa City.Google Scholar
Knox, J. C. (1989). Longand short-term episodic storage and removal of sediment in watersheds of southwestern Wisconsin and northwestern Illinois. In “Sediment and the Environment. Proceedings of the Baltimore Symposium, May, 1989,” pp. 157164. Publication 184, International Association of Hydrological Science, Wallingford, U.K. Google Scholar
Krumbein, W. C. (1937). Sediments and exponential curves. Journal of Geology 45, 577601.Google Scholar
Krumbein, W. C., and Pettijohn, F. J. (1938). “Manual of Sedimentary Petrography.” D. Appleton-Century, New York.Google Scholar
Leigh, D. S. (1991). “Origin and Paleoenvironment of the Upper Mississippi Valley Roxana Silt.” Unpublished Ph.D. dissertation, University of Wisconsin, Madison.Google Scholar
Leighton, M. M. (1917). The Iowan glaciation and the so-called Iowan loess deposits. Proceedings of the Iowa Academy of Science 24, 8792.Google Scholar
Leverett, F. (1932). “Quaternary Geology of Minnesota and Parts of Adjacent States.” Professional Paper 161. U.S. Geological Survey, Washington, DC (Includes map at scale of 1:500,000).Google Scholar
Lively, R. S. Bettis, E. A. III Hallberg, G. R., and Hobbs, H. (1987). An exposure of the Sangamon Soil in southeastern Minnesota. Proceedings of (he Iowa Academy of Science 94, 111115.Google Scholar
Mason, J. A. (1992). “Loess Distribution and Soil Landscape Evolution, Southeastern Minnesota.” Unpublished M.S. thesis, University of Minnesota.Google Scholar
McKay, E. D. (1979). Wisconsinan loess stratigraphy of Illinois. In“Wisconsinan, Sangamonian, and lllinoian Stratigraphy in Central Illinois,” Guidebook 13, pp. 95108. Illinois Geological Survey.Google Scholar
Putman, B. R. Jansen, I. J., and Follmer, L. R. (1988). Loessial soils: their relationship to width of the source valley in Illinois. Soil Science 146, 241247.Google Scholar
Pye, K. (1987). “Aeolian Dust and Dust Deposits.” Academic Press, New York.Google Scholar
Ruhe, R. V, (1954). Relations of the properties of Wisconsin loess to topography in western Iowa. American Journal of Science 252, 663672.Google Scholar
Ruhe, R. V. (1969). “Quaternary Landscapes in Iowa.” Iowa State Univ. Press, Ames.Google Scholar
Ruhe, R. V. (1983). Depositional environment of Late Wisconsin loess in midcontinental United States. In “Late-Quaternary Environments of the United States” (Wright, H. E. Jr., Ed.), Vol. 1, pp. 130137. Univ. of Minnesota Press, Minneapolis.Google Scholar
Ruhe, R. V. Daniels, R. B., and Cady, J. G. (1967). “Landscape Evolution and Soil Formation in Southwestern Iowa.” Technical Bulletin 1349. U.S. Department of Agriculture, Washington, DC.Google Scholar
Ruhe, R. V. Dietz, W. P. Fenton, T. E., and Hall, G. F. (1968). “Iowan Drift Problem, Northeastern Iowa.” Report of Investigations 7, Iowa Geological Survey, Iowa City.Google Scholar
Schwert, D. P., and Ashworth, A. C. (1992). Fossil insect assemblages of the last glacial maximum (21,000-16,500 B.P.) in the Upper Midwest. “Abstracts with Programs,” p. 63. North-Central Section, Geological Society of America.Google Scholar
Simonson, R. W., and Hutton, C. E. (1954). Distribution curves for loess. American Journal of Science 252, 99105.CrossRefGoogle Scholar
Smith, G. D. (1942). “Illinois Loess—Variations in Its Properties and Distribution.” Bulletin 490. Illinois Agricultural Experiment Station, Urbana.Google Scholar
West, L. T. Rutledge, E. M., and Barber, D. M. (1980). Sources and properties of loess deposits on Crowley’s Ridge in Arkansas. Soil Science Society of American Journal 44, 353358.Google Scholar
Worcester, B. K. (1973). “Soil Genesis on the Stable Primary Divides of the Southeastern Iowa loess Province.” Unpublished Ph.D. dissertation, Iowa State University.Google Scholar