Hostname: page-component-8448b6f56d-sxzjt Total loading time: 0 Render date: 2024-04-19T20:04:03.764Z Has data issue: false hasContentIssue false
  • English
  • Français

Climatic Implications of the Late Quaternary Alluvial Record of a Small Drainage Basin in the Central Great Plains

Published online by Cambridge University Press:  20 January 2017

Alan F. Arbogast  and
William C. Johnson
Get access Rights & Permissions [Opens in a new window]

Abstract

Four late-Quaternary alluvial fills and terraces are recognized in Wolf Creek basin, a small (163 km2) drainage in the Kansas River system of the central Great Plains. Two terraces were created during the late Pleistocene: the T-4 is a fill-top terrace underlain by sand and gravel fill (Fill I), and the T-3 is a strath terrace cut on the Cretaceous Dakota Sandstone. Both Fill II (early Holocene) and Fill III (late Holocene) are exposed beneath the T-2, a Holocene fill-top terrace. The T-1 complex, consisting of one cut and three fill-top terraces, is underlain by Fills III and IV. A poorly developed floodplain (T-0) has formed within the past 1000 yr. As valleys in Wolf Creek basin filled during the early Holocene, an interval of soil formation occurred about 6800 yr B.P. Early Holocene fill has been found only in the basin's upper reaches, indicating that extensive erosion during the middle Holocene removed most early-Holocene fill from the middle and lower reaches of the basin. Valley filling between 5000 and 1000 yr B.P. was interrupted by soil formation about 1800, 1500, and 1200 yr B.P. As much as 6 m of entrenchment has occurred in the past 1000 yr. Holocene events in Wolf Creek basin correlate well with those in other localities in the central Great Plains, indicating that widespread changes in climate, along with adjustments driven by complex response, influenced fluvial activity.

Type
Articles
Information
Quaternary Research , Volume 41 , Issue 3 , May 1994 , pp. 298 - 305
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

Aber, J. S., (1992). Chert gravel, drainage development, and sinkhoJes in the Walnut Basin, south-central Kansas. Transactions of the Kansas Academy of Science 95, 109121.Google Scholar
Ahlbrandt, T. S. Swinehart, J. B., and Maroney, D. G. (1983). The dynamic Holocene dune fields of the Great Plains and Rocky Mountains basins, USA. In “Eolian Sediments and Processes” (Brookfield, M. E., and Ahlbrandt, T. S., Eds.), pp. 379406. Elsevier, Amsterdam.Google Scholar
Antevs, E. (1995). Geologic-climatic dating in the West. American Antiquity 20, 317335.Google Scholar
Arbogast, A. F. (1991). “Late-Quaternary Evolution of a Small Basin in the Kansas River System: Wolf Creek.” Unpublished M.A. thesis, University of Kansas.Google Scholar
Arbogast, A. F. (1993). Paleoenvironments and geomorphic processes on the Great Bend Praine in Kansas. “Abstracts with Programs, Vol. 25, p. A-58. Geological Society of America, Boulder. [Abstract] Google Scholar
Berry, D. W. (1952). Geology and groundwater resources of Lincoln County, Kansas. Kansas Geological Survey Bulletin, 95.Google Scholar
Brakenridge, G. R. (1980). Widespread episodes of stream erosion during the Holocene and their climatic cause. Nature 283, 655656.CrossRefGoogle Scholar
Brice, J. C. (1964). “Channel Patterns and Terraces of the Loup Rivers in Nebraska,” pp. 141. U.S. Geological Survey, Professional Paper 422-D.Google Scholar
Brice, J. C. (1966). “Erosion and Deposition in the Loess-Mantled Great Plains, Medicine Creek Drainage, Nebraska,” pp. 255339. U.S. Geological Survey Professional Paper 352-H.Google Scholar
Bull, Williams, B. (1991). “Geomorphic Responses to Climate Change.” Oxford Univ. Press, New York.Google Scholar
COHMAP Members (1988). Climatic changes of the last 18,000 years: observations and model simulations. Science 241, 10431052.Google Scholar
Dort, W. Jr., (1987). Type descriptions of Kansas River terraces. In“Quaternary Environments of Kansas” (Johnson, W. C., Ed.), pp. 103107. Kansas Geological Survey, Lawrence, KS.Google Scholar
Dort, W. Jr. Zeller, E. J., and Martin, L. D. (1993). Extensive late-Quaternary faulting in the mid-continent Great Plains. “Abstracts with Programs,” Vol. 25, p. A-70. Geological Society of America, Boulder, CO. [Abstract] Google Scholar
Fredlund, G. G., and Jaumann, P. J. (1987). Late Quaternary palynological and paleobotanical records from the central Great Plains. In“Quaternary Environments of Kansas” (Johnson, W. C., Ed.), pp. 167178. Kansas Geological Survey, Lawrence, KS.Google Scholar
Forman, S. L., and Maat, P. (1990). Stratigraphic evidence for late Quaternary dune activity near Hudson on the Piedmont of northern Colorado. Geology 75, 745748.Google Scholar
Frye, J. C., and Leonard, A. B. (1952). “Pleistocene Geology of Kansas.” Kansas Geological Survey Bulletin 99, Lawrence, KS.Google Scholar
Hall, S. A. (1990). Channel trenching and climatic change in the southern Great Plains. Geology 18, 342345.2.3.CO;2>CrossRefGoogle Scholar
Hildebrand, G. M. Steeples, D. W. Knapp, R. W„ Miller, R. D., and Bennett, B. C. (1988). Microearthquakes in Kansas and Nebraska 1977-1987. Seismological Research Letters 59, 159163.Google Scholar
Holliday, V. T. (1987). Middle Holocene drought on the southern High Plains. Geoarchaeology 2, 317329.Google Scholar
Johnson, W. C. (1988). Stratigraphic and cultural resolution of the Altithermal in the central Great Plains. “Abstracts with Programs,” Vol. 20, p. A-36. Geological Society of America, Boulder, CO. [Abstract] Google Scholar
Johnson, W. C. (1991). Buried soil surfaces beneath the Great Bend Prairie of central Kansas and Archaeological Implications. Current Research in the Pleistocene 8, 108110.Google Scholar
Johnson, W. C., and Logan, B. (1990). Geoarchaeology of the Kansas River basin, central Great Plains. In “Archaeological Geology of North America” (Lasca, N. P. and Donahue, J., Eds.), Centennial Special Vol. 4, pp. 267299. Geological Society of America, Boulder, CO.Google Scholar
Johnson, W. C., and Martin, C. W. (1987). Holocene alluvialstratigraphic studies from Kansas and adjoining states of the east-central Great Plains. In “Quaternary Environments of Kansas” (Johnson, W. C., Ed.), pp. 109122. Kansas Geological Survey, Lawrence, KS.Google Scholar
Knox, J. C. (1983). Responses of river systems to Holocene climates. In “Late-Quaternary Environments of the United States, the Holocene” (Wright, H. E., Ed.), pp. 2641. Univ. Minnesota Press, Minneapolis, MN.Google Scholar
Kurmann, M. H. (1985). An opal phytolith and palynomorph study of extant and fossil soils in Kansas (U.S.A.). Palaeogeography, Palaeoclimatology, and Palaeoecology 45, 217235.Google Scholar
Kutzbach, J. E. (1985). Modeling of paleoclimates. Advances in Geophysics 28A, 159196.Google Scholar
Mandel, R. D. (1988). Geomorphology of the Smoky Hill River valley at Kanopolis Lake, Northcentral Kansas. In “An Archaeological and Geomorphological Survey of Kanopolis Lake, Northcentral Kansas” (Schmits, L. J., Ed.), pp. 4972. Environmental Systems Analysis, Inc., Mission, KS.Google Scholar
Mandel, R. D. (1992). Soils and Holocene landscape evolution in central and southern Kansas: Implications for archaeological research. In “Soils and Archaeology” (Holliday, V. T., Ed.), pp. 41100. Smithsonian Institution Press, Washington, DC.Google Scholar
Mandel, R. D. Reynolds, J. D. Williams, B. G., and Wulfkuhle, V. A. (1991). “Upper Delaware River and Tributaries Watershed: Results of Geomorphological and Archeological Studies in Atchison, Brown, Jackson, and Nemaha Counties, Kansas.” Kansas State Historical Society Contract Archeology Publication 9, Topeka, KS.Google Scholar
Martin, C. W. (1992a). Late Quaternary sedimentation and paleoenvironmental change in the Republican River basin, southcentral, Nebraska. Quaternary Research 37, 315322.Google Scholar
Martin, C. W. (1992b). The response of fluvial systems to climate change: An example from the central Great Plains. Physical Geography 13, 101114.Google Scholar
May, D. W. (1989). Holocene alluvial fills in the South Loup valley, Nebraska. Quaternary Research 32, 117120.Google Scholar
May, D. W. (1991). Radiocarbon ages of the Elba valley fill in Cooper’s Canyon, Elba, Nebraska. In “Nebraska Academy of Sciences 101st Annual Meeting, Proceedings,” 5960.Google Scholar
May, D. W. (1992). Late Holocene valley-bottom aggradation and erosion in the South Loup River valley, Nebraska, Physical Geography 13, 115132.Google Scholar
Muhs, D. R. (1985). Age and paleoclimatic significance of Holocene sand dunes in northeastern Colorado. Annals of the Association of American Geographers 75, 566582.Google Scholar
Osterkamp, W. R. Fenton, M. M. Gustavson, T. C. Hadley, R. F. Holliday, V. T. Morrison, R. B., and Toy, T. L. (1987). Great Plains. In “Geomorphic Systems of North America” (Graf, W. L., Ed.), Centennial Special Volume 2, pp. 163210. Geological Society of America, Boulder, CO.Google Scholar
Schultz, C. B. Lueninghoener, G. C., and Frankforter, W. D. (1948). Preliminary geomorphological studies of the Lime Creek Area. Bulletin of the University of Nebraska State Museum 3, 3142.Google Scholar
Schumm, S. A. (1977). “The Fluvial System.” Wiley, New York.Google Scholar
Schumm, S. A., and Parker, R. S. (1973). Implications of complex response of drainage systems for quaternary alluvial stratigraphy. Nature 243, 99100.Google Scholar
Swinehart, J. B. (1990). Wind-blown deposits. In “An Atlas of the Sand Hills” (Bleed, A. and Flowerday, C., Ed.), Conservation and Survey Division, University of Nebraska, Resource Atlas No. 5a, pp. 4356. Lincoln, NE.Google Scholar
Wendland, W. M. (1982). Geomorphic responses to climate forcing factors during the Holocene. In “Space and Time in Geomorphology” (Thom, C. E., Ed.), pp. 355371. Allen and Unwin Ltd., London.Google Scholar
Wendland, W. M., and Bryson, R. A. (1974). Dating climatic episodes of the Holocene. Quaternary Research 4, 924 Google Scholar