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Athens Subepisode (Wisconsin Episode) non-glacial and older glacial sediments in the subsurface of southwestern Michigan, USA

Published online by Cambridge University Press:  20 January 2017

Patrick M. Colgan
Affiliation:
Department of Geology, Grand Valley State University, Allendale, MI 49401, USA
Christopher A. Vanderlip
Affiliation:
Department of Geology, Grand Valley State University, Allendale, MI 49401, USA
Katelynn N. Braunschneider
Affiliation:
Peerless Midwest INC, 46545, USA

Abstract

We describe the first complete sediment core to bedrock in southwestern Michigan of a radiocarbon defined sequence of Michigan Subepisode (Marine Oxygen Isotope Stage [MIS] 2) glacial sediments, Athens Subepisode (MIS 3) non-glacial sediments, and two older tills using sedimentological, lithological, and radiocarbon analyses. Organics from Athens Subepisode lacustrine and palustrine sediments yield radiocarbon ages of 41,920–42,950 and 43,630–45,340, and > 43,500 14C yr BP. We propose the name Port Sheldon Formation for these organic-bearing sediments. We interpret the underlying diamictons as two basal tills separated by glaciolacustrine fines. The youngest till (Hemlock Crossing till) lying below the Port Sheldon Formation is a dark gray, gravel-poor clay loam to loam with a mean kaolinite–illite ratio of 0.98 ± 0.04. The oldest till (Glenn Shores till) is a dark grayish brown, gravel-rich, clay loam to sandy loam with mean kaolinite–illite ratio of 1.22 ± 0.08. About 130 water-well records demonstrate that organic sediments and underlying diamictons are common in the subsurface of Ottawa County. These tills are likely Illinois Episode (MIS 6) or older, but an Ontario Subepisode (MIS 4) age cannot be ruled out. Deep bedrock basins in Lower Michigan provide an untapped archive of pre-Michigan Subepisode history.

Type
Articles
Copyright
University of Washington

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References

Anderson, R.C. Pebble and sand lithology of the major Wisconsin glacial lobes of the Central Lowland. Geological Society of America Bulletin 68, (1957). 14151449.Google Scholar
Bajc, A.F., Karrow, P.F., Yansa, C.H., Curry, B.B., Nekola, J.C., Seymour, K.L., and Mackie, G.L. Geology and paleoecology of a Middle Wisconsin fossil occurrence in Zorra Township, southwestern Ontario, Canada. Canadian Journal of Earth Sciences 52, (2015). 386404.Google Scholar
Baker, R.G., Bettis, E.A. III, Mandel, R.D., Dorale, J.A., and Fredlund, G.G. Mid-Wisconsinan environments on the eastern Great Plains. Quaternary Science Reviews 28, (2009). 873889.Google Scholar
Benn, D., and Evans, D.J.A. Glaciers and Glaciation. 2nd ed. (2010). Hodder Arnold, New York.Google Scholar
Berg, R.C., McKay, E.D.I.I.I., Goble, R.J., and Wang, H. Age of the Winnebago Formation of north-central Illinois as determined by optically stimulated luminescence dating. Illinois State Geological Survey Circular 580, (2013). (15 pp.)Google Scholar
Beukema, S.P. Stratigraphy of Lake Michigan lobe deposits in Van Buren County, Michigan. (M.S. thesis) (2003). Department of Geosciences, Western Michigan University, Kalamazoo.Google Scholar
Bretz, J.H. Glacial Grand River, Michigan. Michigan Academy of Science, Arts, and Letters, Papers 38. (1953). 359382.Google Scholar
Buckley, J., and Willis, E.H. Isotope radiocarbon measurements IV. Radiocarbon 14, (1972). 114139.Google Scholar
Carlson, A.E., Principato, S.M., Chapel, D.M., and Mickelson, D.M. Quaternary geology of Sheboygan County, Wisconsin. Wisconsin Geological and Natural History Survey Bulletin 106, (2011). (32 pp., 2 pls)Google Scholar
Clark, P.U., Clague, J.J., Curry, B.B., Dremanis, A., Hicock, S.R., Miller, G.H., Berger, G.W., Eyles, N., Lamonth, M., Miller, B.B., Mott, J., Oldale, R.N., Stea, R.R., Szabo, J.P., Thorleifson, L.H., and Vinvent, J.S. Initiation and development of the Laurentide and Cordilleran Ice Sheets following the last interglaciation. Quaternary Science Reviews 12, (1993). 79114.Google Scholar
Clark, P.U., Dyke, A.S., Shakun, J.D., Carlson, A.E., Clark, J., Wohlfarth, B., Mitrovica, J.X., Hostetler, S.W., and McCabe, A.M. The Last Glacial Maximum. Science 325, (2009). 710714.Google Scholar
Crane, H.R., and Griffin, J.B. University of Michigan radiocarbon dates VI. Radiocarbon 3, (1961). 105125.Google Scholar
Curry, B.B. Absence of Altonian glaciation in Illinois. Quaternary Research 31, (1989). 113.Google Scholar
Curry, B.B., and Follmer, L.R. The last interglacial–glacial transition in Illinois: 123–25 ka. Clark, P.U., and Lea, P.D. The last interglacial–glacial transition in North America. 270, (1992). Geological Society of America, Special Paper, Boulder, Colorado. 7188.Google Scholar
Curry, B.B., and Grimley, D.A. Provenance, age, and environment of mid-Wisconsinan slackwater lake sediment in the St. Louis Metro East area, USA. Quaternary Research 65, (2006). 108122.Google Scholar
Curry, B.B., and Pavich, M.J. Absence of glaciation in Illinois during marine isotope stages 3 through 5. Quaternary Research 46, (1996). 1926.CrossRefGoogle Scholar
Curry, B.B., Grimley, D.A., and McKay, E.D. Quaternary Glaciations in Illinois. Ehlers, J., Gibbard, P.L., and Hughes, P.D. Quaternary Glaciations — Extent and Chronology: A Closer Look. Developments in Quaternary Science (2011). Elsevier Science, Amsterdam. 467487.Google Scholar
Curry, B.B., Hajic, E.R., Clark, J.A., Befus, K.M., Carrell, J.E., and Brown, S.E. The Kankakee Torrent and other large meltwater flooding events during the last deglaciation, Illinois, USA. Quaternary Science Reviews 90, (2014). 2236.Google Scholar
Dearing, J. Environmental Magnetic Susceptibility. (1999). Bartington Instruments, Oxford.Google Scholar
Eschman, D.F. Some evidence of mid-Wisconsinan events in Michigan. Michigan Academician 12, (1980). 423436.Google Scholar
Eschman, D.F., and Mickelson, D.M. Correlation of glacial deposits of the Huron, Lake Michigan and Green Bay Lobes in Michigan and Wisconsin. Quaternary Science Reviews 5, (1986). 5357.Google Scholar
Eyles, N., Eyles, C.H., and Miall, A.D. Lithofacies types and vertical profile models; an alternative approach to the description and environmental interpretation of glacial diamict and diamictite sequences. Sedimentology 30, (1983). 393410.Google Scholar
Farrand, W.R., and Eschman, D.F. Glaciation of the Southern Peninsula of Michigan: a review. Michigan Academician 7, (1974). 3156.Google Scholar
Flint, A.C. Stratigraphic analysis of diamicton units in north-central St. Joseph County, Michigan. (M.S. thesis) (1999). Department of Geosciences, Western Michigan University, Kalamazoo.Google Scholar
Gardner, R.C. Lithologic and Stratigraphic Analysis of Glacial Diamictons, Sturgis, Michigan. (M.S. thesis) (1997). Department of Geosciences, Western Michigan University, Kalamazoo.Google Scholar
Goldthwait, R.P. Historical overview of early Wisconsin glaciation. Clark, P.U., and Lea, P.D. The last interglacial–glacial transition in North America. Boulder, Colorado. Geological Society of America, Special Paper 270, (1992). 1318.Google Scholar
Grimley, D.A. Glacial and nonglacial sediment contributions to Wisconsin Episode loess in the central United States. Geological Society of America Bulletin 112, (2000). 14751495.2.0.CO;2>CrossRefGoogle Scholar
Grimley, D.A., and Oches, E.A. Amino acid geochronology of gastropod-bearing Pleistocene units in Illinois, central USA. Quaternary Geochronology 25, (2015). 1025.Google Scholar
Hansel, A.K., and Johnson, W.H. Wedron and Mason groups: lithostratigraphic reclassification of deposits of the Wisconsin Episode. Illinois State Geological Survey Bulletin 104, (1996). Google Scholar
Hansen, E.C., Arbogast, A.F., Packman, S.C., and Hansen, B. Post-Nipissing origin of a backdune complex along the southeastern shore of Lake Michigan. Physical Geography 23, (2003). 233244.Google Scholar
Hansen, E.C., Arbogast, A.F., van Dijk, D., and Yurk, B. Growth and migration of parabolic dunes along the southeastern Coast of Lake Michigan. Journal of Coastal Research 209–214, (2006). Google Scholar
Hicock, S.R., and Dreimanis, A. Sunnybrook drift indicates a grounded early Wisconsin glacier in the Lake Ontario basin. Geology 17, (1989). 169172.Google Scholar
Holman, J.A. A 25,000-year old duck, more evidence for a Michigan Wisconsinan interstadial. American Midland Naturalist 96, (1976). 501503.Google Scholar
Howard, J.L. Late Pleistocene glaciolacustrine sedimentation and paleogeography of southeastern Michigan, USA. Sedimentary Geology 223, (2010). 126142.Google Scholar
Hughes, R.E., Moore, D.M., and Glass, H.D. Qualitative and quantitative analysis of clay minerals in soils. Amonette, J.E., and Zelazny, L.W. Quantitative Methods in Soil Mineralogy. (1994). Soil Science Society of America Miscellaneous Publication, Madison, WI. 330359.Google Scholar
Hughes, P.D., Gibbard, P.L., and Ehlers, J. Timing of glaciation during the last glacial cycle: evaluating the concept of a global ‘Last Glacial Maximum’ (LGM). Earth-Science Reviews 125, (2013). 171198.Google Scholar
Jacobs, P.M., Konen, M.E., and Curry, B.B. Pedogenesis of a catena of the Farmdale-Sangamon Geosol complex in the north central United States. Palaeogeography Palaeoclimatology Palaeoecology 282, (2009). 119132.CrossRefGoogle Scholar
Johnson, W.H. Stratigraphy and correlation of the glacial deposits of the Lake Michigan Lobe prior to 14 ka BP. Quaternary Science Reviews 5, (1986). 1722.Google Scholar
Johnson, W.H., Hansel, A.K., Bettis, E.A. II, Karrow, P.F., Larson, G.J., Lowell, T.V., and Schneider, A.F. Late Quaternary temporal and event classifications, Great Lakes Region, North America. Quaternary Research 47, (1997). 112.Google Scholar
Kapp, R.O. A 24,000-year-old Jefferson Mammoth from Midland County, Michigan. Michigan Academician 3, (1970). 9599.Google Scholar
Kapp, R.O. Remains from a Wisconsinan interstadial dated 25,000 B.P., Muskegon Co., Michigan. American Midland Naturalist 100, (1978). 506509.Google Scholar
Karrow, P.F., Seymour, K.L., Miller, B.B., and Mirecki, J.E. Pre-Late Wisconsinan Pleistocene biota from southeastern Michigan, U.S.A. Palaeogeography, Palaeoclimatology, Palaeoecology 133, (1997). 81101.Google Scholar
Karrow, P.F., Dreimanis, A., and Barnett, P.J. A proposed diachronic revision of late Quaternary time-stratigraphic classification in the eastern and northern Great Lakes area. Quaternary Research 54, (2000). 112.Google Scholar
Kehew, A.E. Glacial-lake outburst erosion of the Grand Valley, Michigan, and impacts on glacial lakes in the Lake Michigan Basin. Quaternary Research 39, (1993). 3644.Google Scholar
Kehew, A.E., Beukema, S.P., Bird, B.C., and Kozlowski, A.L. Fast flow of the Lake Michigan Lobe: evidence from sediment-landform assemblages in southwestern Michigan, USA. Quaternary Science Reviews 24, (2005). 23352353.Google Scholar
Kehew, A.E., Esch, J.M., Kozlowski, A.L., and Ewald, S.K. Glacial landsystems and dynamics of the Saginaw Lobe of the Laurentide Ice Sheet, Michigan, USA. Quaternary International 260, (2012). 2131.Google Scholar
Larson, G.J. Ice-margin fluctuations at the end of the Wisconsin Episode, Michigan, USA. Ehlers, J., Gibbard, P.L., and Hughes, P.D. Quaternary Glaciations — Extent and Chronology: A Closer Look. Developments in Quaternary Science (2011). Elsevier Science, Amsterdam. 489497.Google Scholar
Larson, G.J., and Monaghan, W.G. Lake phases and glacio–fluvial sequences of the Lake Michigan Basin: Southwestern Michigan. Larson, G.J., and Monaghan, W.G. Guidebook of the Friends of the Pleistocene field Conference May 21–21, 1988: Wisconsinan and Holocene Stratigraphy in southwestern Michigan, Lansing, Michigan. (1988). 114.Google Scholar
Larson, G., and Schaetzl, R. Origin and evolution of the Great Lakes. Journal of Great Lakes Research 27, (2001). 518546.Google Scholar
Leverett, F., and Taylor, F.B. The Pleistocene of Indiana and Michigan and the History of the Great Lakes. (1915). United States Geological Survey, Washington.Google Scholar
Lewis, D.W., and McConchie, D. Practical Sedimentology. (1994). Chapman and Hall, New York.Google Scholar
Lingle, D. Origin of High Levels of Ammonium in Groundwater, Ottawa County, Michigan. (M.S. Thesis) (2013). Department of Geosciences, Western Michigan University, Kalamazoo.Google Scholar
MDEQ, Scanned water well retrieval system. http://www.deq.state.mi.us/welllogs/default.as (2009). Google Scholar
MDEQ Wellogic water well retrieval system. http://www.deq.state.mi.us/welllogs/default.as (2012). Google Scholar
Mickelson, D.M., and Socha, B.J. Quaternary Geology of Calumet and Manitowoc Counties, Wisconsin. (2015). Wisconsin Geological and Natural History Survey, Bulletin, (in press)Google Scholar
Miller, N.G. Pollen analysis of deeply buried Quaternary sediments from southern Michigan. American Midland Naturalist 89, (1973). 217223.Google Scholar
Monaghan, W.G. Systematic variation in the clay–mineral composition of till sheets; evidence for the Erie Interstade in the Lake Michigan basin. Schneider, A.F., and Fraser, G.S. Late Quaternary History of the Lake Michigan Basin. (1990). Geological Society of America, Boulder, Colorado. 4350.Google Scholar
Monaghan, W.G., and Larson, G.J. Late Wisconsinan drift stratigraphy of the Saginaw ice lobe in south-central Michigan. Geological Society of America Bulletin 97, (1986). 324328.Google Scholar
Monaghan, W.G., Larson, G.J., and Gephart, G.D. Late Wisconsinan drift stratigraphy of the Lake Michigan Lobe in southwestern Michigan. Geological Society of American Bulletin 97, (1986). 329334.Google Scholar
Nicks, L. The Glacial Geology of Southern St. Joseph County, Michigan. (Ph.D. dissertation) (2004). Department of Geosciences, Western Michigan University, Kalamazoo.Google Scholar
Rieck, R.L., and Winters, H.A. Distribution and significance of glacially buried organic matter in Michigan's Southern Peninsula. Physical Geography 1, (1980). 7489.Google Scholar
Rieck, R.L., and Winters, H.A. Low-altitude organic deposits in Michigan: evidence for pre-Woodfordian Great Lakes and paleosurfaces. Geological Society of American Bulletin 93, (1982). 726734.Google Scholar
Rieck, R.L., Winters, H.A., Mokma, D.L., and Mortland, M.M. Differentiation of surficial glacial drift in southeastern Michigan from 7-Å/10-Å X-ray diffraction ratios of clays. Geological Society of America Bulletin 90, (1979). 216220.Google Scholar
Rovey, C.W., and Balco, G. Periglacial climate at the 2.5 Ma onset of Northern Hemisphere glaciation inferred from the Whippoorwill Formation, northern Missouri, USA. Quaternary Research 73, (2010). 151161.Google Scholar
Roy, M., Clark, P.U., Barendregt, R.W., Glasmann, J.R., and Enkin, R.J. Glacial stratigraphy and paleomagnetism of late Cenozoic deposits of the north-central United States. Geological Society of America Bulletin 116, (2004). 3041.Google Scholar
Schneider, A.F., and Need, E.A. Lake Milwaukee: an “early” proglacial lake in the Lake Michigan basin. Karrow, P.F., and Calkin, P.E. Quaternary Evolution of the Great Lakes. 30, (1985). Geological Association of Canada Special Paper, 5562.Google Scholar
Soller, D.R. Map showing the thickness and character of Quaternary sediments in the glaciated United States east of the Rocky Mountains - northern Great Lakes states and central Mississippi Valley states, the Great Lakes, and southern Ontario (80 degrees 31' to 93 degrees west longitude). United States Geological Survey. (1998). Google Scholar
Stewart, M.T., and Mickelson, D.M. Clay mineralogy and relative age of tills in north-central Wisconsin. Journal of Sedimentary Petrology 46, (1976). 200205.Google Scholar
Stuiver, M., Huesser, C.J., and Yang, I.C. North American glacial history extended to 75,000 years. Science 200, (1978). 1621.Google Scholar
Sullivan, B.M., Spiker, E., and Rubin, M. U.S. Geological Survey radiocarbon dates XL. Radiocarbon 12, (1970). 319334.Google Scholar
Syverson, K.M., and Colgan, P.M. The Quaternary of Wisconsin: a review of stratigraphy and glaciation history. Ehlers, J., and Gibbard, P.L. Quaternary Glaciations — Extent and Chronology: Part II — North America. (2004). Elsevier, Amsterdam, Netherlands. 295311.Google Scholar
Syverson, K.M., and Colgan, P.M. The Quaternary of Wisconsin: an updated review of stratigraphy, glacial history and landforms. Ehlers, J., Gibbard, P.L., and Hughes, P.D. Quaternary Glaciations — Extent and Chronology: A Closer Look. (2011). Elsevier, Amsterdam, Netherlands. 537552.Google Scholar
Szabo, J.P. Reevaluation of early Wisconsinan stratigraphy of northern Ohio. Clark, P.U., and Lea, P.D. The Last Interglacial–Glacial Transition in North America: Boulder, Colorado. Geological Society of America, Special Paper 270, (1992). 99107.Google Scholar
Ullman, D.J., Carlson, A.E., LeGrande, A.N., Anslow, F.S., Moore, A.K., Caffee, M., Syverson, K.M., and Licciardi, J.M. Southern Laurentide ice-sheet retreat synchronous with rising boreal summer insolation. Geology 43, (2015). 2326.Google Scholar
Winters, H.A., and Rieck, R.L. Late glacial terrain transformation in Michigan. Michigan Academician 23, (1991). 137148.Google Scholar
Winters, H.A., Alford, J.J., and Rieck, R.L. The anomalous Roxana Silt and mid-Wisconsinan events in and near southern Michigan. Quaternary Research 29, (1988). 2535.Google Scholar
Wong, S.A. Stratigraphic Analysis of Diamicton Units in Southern Allegan County, Michigan. (Dissertation) (2002). Department of Geosciences, Western Michigan University, Google Scholar
Zumberge, J.H., and Benninghoff, W.S. A mid-Wisconsinan peat in Michigan, U.S.A.. Pollen et Spores 11, (1969). 585601.Google Scholar