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An analysis of the late glacial lake levels within the western Lake Superior basin based on digital elevation models

Published online by Cambridge University Press:  20 January 2017

Andy Breckenridge*
Affiliation:
Natural Sciences Department, University of Wisconsin-Superior, Belknap and Catlin, Superior, WI 54880, USA
*
E-mail address:[email protected].

Abstract

This study establishes a detailed lake-level history for the Lake Superior basin by mapping strandlines from 10-m and 3-m digital elevation models. There are 24 levels above the mid-Holocene Nipissing level, and elevations increase along a direction of 23.1° due to post-glacial rebound. The highest level, the Epi-Duluth, is steeper than subsequent levels and may pre-date the Lake View ice advance into the western Lake Superior basin at the end of the Younger Dryas stade. The most prominent level is the Duluth, ca. 10,800 cal yr BP. Ice retreat exposed successively lower outlets, routing overflow to the Lake Michigan and Huron basins. By 10,600 cal yr BP, lake levels in the western Superior basin had dropped almost 200 m. This transformative period is complicated by multiple basin-wide events: the influx of glacial Lake Agassiz overflow, the creation of three sub-aqueous moraines, and a red to gray color transition in basin sediments. A later drawdown event has been hypothesized to have initiated the 9300 cal yr BP cooling event, but this flood was much smaller than estimated previously. If freshwater triggered the 9300 cal yr BP event, the source of the water must have been Lake Agassiz, not Lake Superior.

Type
Original Articles
Copyright
University of Washington

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References

Agassiz, L., (1850). Lake Superior: Its Physical Character, Vegetation, and Animals Compared to Those of Other Similar Regions. Gould, Kendall, and Lincoln, Boston.Google Scholar
Bacig, E.J., Huber, J.K., (1993). A late glacial sequence from the Portage river channel, northeast Minnesota. Current Research in the Pleistocene 10, 8789.Google Scholar
Bajc, A.F., (1986). Molluscan paleoecology and Superior basin water levels, Marathon, Ontario. Unpublished M.S. thesis, University of Waterloo, 271 pp.Google Scholar
Black, R.F., (1976). Quaternary geology of Wisconsin and contiguous Upper Michigan. Mahaney, W.C. Quaternary Stratigraphy of North America. Dowden, Hutchinson, and Ross, Stroudesburg, Pennsylvania.93117.Google Scholar
Blewett, W.L., (2009). Understanding Ancient Shorelines in the National Parklands of the Great Lakes, Pictured Rocks Resource Report. US Government Printing Office, Washington, D.C..Google Scholar
Boyd, M., Teller, J.T., Yang, Z., Kingsmill, L., Shultis, C., (2012). An 8,900-year-old forest drowned by Lake Superior: hydrological and paleoecological implications. Journal of Paleolimnology 47, 339355.Google Scholar
Breckenridge, A.J., (2006). Lake Superior Varves: Records of Lake Agassiz Overflow and Ice Sheet Dynamics. University of Minnesota, 250(PhD dissertation).Google Scholar
Breckenridge, A., (2007). Lake Superior varve stratigraphy and implications for eastern Lake Agassiz outflow from 10,700 to 9,040 cal BP (9.5–8.1 14C ka). Palaeogeography, Palaeoclimatology, Palaeoecology 246, 4561.CrossRefGoogle Scholar
Breckenridge, A., Johnson, T.C., (2009). Paleohydrology of the upper Laurentian Great Lakes from the late glacial to early Holocene. Quaternary Research 71, 397408.Google Scholar
Breckenridge, A.J., Johnson, T.C., Beske-Diehl, S., Mothersill, J.S., (2004). The timing of regional late glacial events and post-glacial sedimentation rates from Lake Superior. Quaternary Science Reviews 23, 23552367.CrossRefGoogle Scholar
Breckenridge, A., Lowell, T.V., Fisher, T.G., Yu, S., (2010). A late Minong transgression in the Lake Superior basin as documented by sediments from Fenton Lake, Ontario. Journal of Paleolimnology 47, 313326.CrossRefGoogle Scholar
Broecker, W.S., Kennett, J., Flower, B., Teller, J.T., Trumbore, S., Bonani, G., Wolfli, W., (1989). Routing of meltwater from the Laurentide Ice Sheet during the Younger Dryas cold episode. Nature 341, 318321.Google Scholar
Carlson, A.E., Clark, P.U., (2012). Ice-sheet sources of sea-level rise and freshwater discharge during the last deglaciation. Reviews of Geophysics 50, Google Scholar
Clarke, P.U., Marshall, S.J., Clarke, G., Hostetler, S.W., Licciardi, J.M., Teller, J.T., (2001). Freshwater forcing of abrupt climate change during the last deglaciation. Science 283, 283287.Google Scholar
Clayton, L., (1984). Pleistocene geology of the Superior region, Wisconsin. Information Circular 46, Wisconsin Geological and Natural History Survey, Madison, Wisconsin. Google Scholar
Colman, S.M., (2002). A fresh look at glacial floods. Science 296, 12511252.Google Scholar
Colman, S.M., Clark, K.A., Clayton, L., Hansel, A.K., Larsen, C.E., (1994). Deglaciation, lake levels, and meltwater discharge in the Lake Michigan basin. Quaternary Science Reviews 13, 879890.Google Scholar
Cowan, W.R., (1985). Deglacial Great Lakes shorelines at Sault Ste Marie, Ontario. Karrow, P.K., Calkin, P.E. Quaternary Evolution of the Great Lakes. Geological Association of Canada Special Paper 30, 3337.Google Scholar
Dell, C.I., (1972). The origin and characteristics of Lake Superior sediments. Proceedings 15th Conference on Great Lakes Research. International Association for Great Lakes Research, 361370.Google Scholar
Drexler, C.W., (1981). Outlet channels for the Post-Duluth lakes in the Upper Peninsula of Michigan. University of Michigan Ann Arbor, 295(PhD dissertation).Google Scholar
Drexler, C.W., Farrand, W.R., Hughes, J.D., (1983). Correlation of glacial lakes in the Superior basin with eastward discharge events from Lake Agassiz. Teller, J.T., Clayton, L. Glacial Lake Agassiz. Geological Association of Canada special paper 26, 309329.Google Scholar
Farrand, W.R., (1960). Former Shorelines in Western and Northern Lake Superior Basin. University of Michigan, Ann Arbor, MI, 266(PhD dissertation).Google Scholar
Farrand, W.R., (1969). The Quaternary history of Lake Superior. Proceedings 12th Conference on Great Lakes Research, Int'l Association of Great Lakes Research. 181197.Google Scholar
Farrand, W.R., Drexler, C.W., (1985). Late Wisconsin and Holocene history of the Lake Superior basin. Karrow, P.K., Calkin, P.E. Quaternary Evolution of the Great Lakes. Geological Association of Canada Special Paper 30, 1732.Google Scholar
Fisher, T.G., Lowell, T.V., (2012). Testing northwest drainage from Lake Agassiz using extant ice margin and strandline data. Quaternary International 260, 106114.CrossRefGoogle Scholar
Fisher, T.G., Whitman, R.L., (1999). Deglacial and lake level fluctuation history recorded in cores, Beaver Lake, Upper Peninsula, Michigan. Journal of Great Lakes Research 25, 263274.CrossRefGoogle Scholar
Flakne, R., (2003). The Holocene vegetation history of Isle Royale National Park, Michigan, U.S.A.. Canadian Journal of Forest Research 33, 11441166.CrossRefGoogle Scholar
Gesch, D.B., (2007). The National Elevation Dataset. Maune, D. Digital Elevation Model Technologies and Applications: The DEM User's Manual. 2nd EditionAmerican Society for Photogrammetry and Remote Sensing, Bethesda, Maryland.99118.Google Scholar
Hack, J.T., (1965). Postglacial drainage evolution and stream geometry in the Ontonagon area. Michigan. U.S. Geological Survey Professional Paper 504B. Google Scholar
Hobbs, H.C., Breckenridge, A., (2011). Ice advances and retreats, inlets and outlets, sediments and strandlines of the western Lake Superior basin. Miller, J.D., Hudak, G.J., Wittkop, C., McLaughlin, P.I. Archean to Anthropocene: Field Guides to the Geology of the Mid-continent of North America, GSA Field Guide. 24, 299315.Google Scholar
Huber, N.K., (1973). Glacial and postglacial geologic history of Isle Royale National Park, Michigan. Geological Survey Professional Paper 754-A.Google Scholar
Hughes, J.D., (1963). Physiography of a Six Quadrangle Area in the Keeweenaw Peninsula North of Portage Lake. Northwestern University, 228(PhD dissertation).Google Scholar
Hyodo, A., Longstaffe, F.J., (2011). The chronostratigraphy of Holocene sediments from four Lake Superior sub-basins. Canadian Journal of Earth Sciences 48, 15811599.CrossRefGoogle Scholar
Johnson, R.G., McClure, B.T., (1976). A model for northern hemisphere continental ice sheet variation. Quaternary Research 6, 325353.CrossRefGoogle Scholar
Johnston, W.A., (1946). Glacial Lake Agassiz, with special reference to the mode of deformation of the beaches. Geological Survey of Canada Bulletin 7, Google Scholar
Johnston, J.W., Thompson, T.A., Wilcox, D.A., Baedke, S.J., (2007). Geomorphic and sedimentologic evidence for the separation of Lake Superior from Lake Michigan and Huron. Journal of Paleolimnology 37, 349364.Google Scholar
Johnston, J.W., Argyilan, E.P., Thompson, T.A., Baedke, S.J., Lepper, K., Forman, S.L., Wilcox, D.A., (2012). A Sault-outlet-referenced mid- to late-Holocene paleohydrograph for Lake Superior constructed from strandplains of beach ridges. Canadian Journal of Earth Sciences 49, 13641371.CrossRefGoogle Scholar
Julig, P.J., McAndrews, J.H., Mahaney, W.C., (1990). Geoarchaeology of the Cummins Site on the beach of proglacial Lake Minong, Lake Superior basin, Canada. Lasca, N.P., Donahue, J.E. Archaeological Geology of North America, Geological Society of America, Centennial Special Volume 4(2), Boulder, CO. 2149.Google Scholar
Knaeble, A.R., Hobbs, H.C., (2009). Surficial geology, pl. 3 of Boerboom, T.J., project manager, Geologic atlas of Carlton County, Minnesota: Minnesota Geological Survey County Atlas C-19. pt. A, 6 pls., scale 1:100,000.Google Scholar
Landmesser, C.W., Johnson, T.C., Wold, R.J., (1982). Seismic reflection study of recessional moraines beneath Lake Superior and their relationship to regional deglaciation. Quaternary Research 17, 173190.CrossRefGoogle Scholar
Larsen, C.E., (1985). Lake Level, uplift, and outlet incision, the Nipissing and Algoma Great Lakes. Karrow, P.K., Calkin, P.E. Quaternary Evolution of the Great Lakes. Geological Association of Canada Special Paper 30, 6377.Google Scholar
Leverett, F., (1929). Moraines and shorelines of the Lake Superior basin. United States Geological Survey Professional Paper 154-A.Google Scholar
Leverett, F., Taylor, F.B., (1915). The Pleistocene of Indiana and Michigan and the history of the Great Lakes. United States Geological Survey Monograph 53, Google Scholar
Leverington, D.W., Teller, J.T., (2003). Paleotopographic reconstructions for the eastern outlets of glacial Lake Agassiz. Canadian Journal of Earth Sciences 40, 12591278.Google Scholar
Leverington, D.W., Teller, J.T., Mann, J.D., (2002). A GIS method for reconstruction of late Quaternary landscapes from isobase data and modern topography. Computers and Geosciences 28, 631639.Google Scholar
Lewis, C.F.M., Thorleifson, L.H., (2003). Empirical modeling of regional glacio-isostatic warping for evaluating drainage system development in Red River valley and Lake Winnipeg basin. Brooks, G.R., George, S.S., Lewis, C.F.M., Medioli, B.E., Nielsen, E., Simpson, S., Thorleifson, L.H. Geoscientific Insights into Red River Flood Hazards in Manitoba: The Final Report of the Red River Flood Project. Natural Resources Canada, .Google Scholar
Lewis, C.F.M., Blasco, S.M., Gareau, P.L., (2005). Glacial isostatic adjustment of the Laurentian Great Lakes basin: using the empirical record of strandline deformation for reconstruction of early Holocene paleo-lakes and discovery of a hydrologically closed phase. Géographie physique et Quaternaire 59, 187210.CrossRefGoogle Scholar
Lewis, C.F.M., (2008). Dry climate disconnected the Laurentian Great Lakes. Eos 89, 52 541542.Google Scholar
Logan, W.E., (1847). North Shore of Lake Superior. Geological Survey of Canada, Report on Progress 1846–1847. 834.Google Scholar
Loope, H.M., Loope, W.L., Goble, R.J., Fisher, T.G., Jol, H.M., (2010). Early Holocene dune building linked to meltwater-driven lowering of glacial Lake Minong in eastern Upper Michigan, USA. Quaternary Research 74, 7381.Google Scholar
Lowell, T., Larson, G.J., Hughes, J.D., Denton, G.H., (1999). Age verification of the Lake Gribben Forest Bed and the Younger Dryas advance of the Laurentide ice sheet. Canadian Journal of Earth Science 36, 383393.Google Scholar
Lowell, T.V., Fisher, T.G., Hajdas, I., Glover, K., Loope, H., Henry, T., (2009). Radiocarbon deglaciation chronology of the Thunder Bay, Ontario Area and implications for ice sheet retreat patterns. Quaternary Science Reviews 28, 15971607.Google Scholar
Lyell, Charles. (1830). Principles of Geology, Being an Attempt to Explain the Former Changes of the Earth's Surface, by Reference to Causes Now in Operation. John Murray, London.Google Scholar
Meissner, K.J., Clark, P.U., (2006). Impact of floods versus routing events on the thermohaline circulation. Geophysical Research Letters 33, 10.1029/2006GL026705(L15704).Google Scholar
Minnesota Department of Natural Resources, . (2011). LiDAR Elevation, Arrowhead Region, NE Minnesota, 2011. http://www.mngeo.state.mn.us/committee/elevation/mn_elev_mapping.html .Google Scholar
Need, E.A., Johnson, M.D., (1984). Stratigraphy and history of glacial deposits, along Wisconsin's Lake Superior shoreline—Wisconsin point to Bark point. Geoscience Wisconsin 9, 2151.Google Scholar
Peltier, W.R., (1994). Ice age paleotopography. Science 265, 195201.Google Scholar
Peltier, W.R., (1998). Postglacial variations in the level of the sea: implications for climate dynamics and solid-earth geophysics. Reviews of Geophysics 36, 603689.Google Scholar
Phillips, B.A.M., Hill, C.L., (1994). The Geology, Glacial, and Shoreline History and Archaeological Potential of the Minnesota North Shore of Lake Superior. Minnesota Department of Natural Resources. Parks Division, St. Paul, Minnesota.Google Scholar
Raymond, R.E., Kapp, R.O., Janke, R.A., (1975). Postglacial and recent sediments of inland lakes of Isle Royale National Park, Michigan. Michigan Academician 7, 453465.Google Scholar
Rea, D.K., Moore jr., T.C., Anderson, T.W., Lewis, C.E.M., Dobson, D.M., Dettman, D.L., Smith, A.J., Mayer, L.A., (1994). Great Lakes paleohydrology: complex interplay of glacial lake levels, and sill depths. Geology 22, 10591602.Google Scholar
Reimer, P.J., (2009). IntCal09 and Marine09 radiocarbon age calibration curves, 0–50,000 years cal BP. Radiocarbon 51, 11111150.Google Scholar
Rooth, C., (1982). Hydrology and ocean circulation. Progress in Oceanography 11, 131149.Google Scholar
Saarnisto, M., (1975). Stratigraphical studies of shoreline displacement of Lake Superior. Canadian Journal of Earth Sciences 12, 300319.Google Scholar
Schaetzl, R.J., Drzyzga, S.A., Weisenborn, B.N., Kincare, K.A., Lepczyk, X.C., Shein, K.A., Dowd, C.M., Linker, J., (2002). Measurement, correlation, and mapping of Glacial Lake Algonquin shorelines in northern Michigan. Annals of the Association of American Geographers 92, 399415.CrossRefGoogle Scholar
Sharpe, D.R., Cowan, W.R., (1990). Moraine formation in northwestern Ontario: product of subglacial fluvial and glaciolacustrine sedimentation. Canadian Journal of Earth Sciences 27, 14781486.Google Scholar
Stanley, G.M., (1932). Abandoned Strands of Isle Royale and Northeastern Lake Superior. University of Michigan, Ann Arbor.158(PhD dissertation).Google Scholar
Stanley, G.M., (1941). Minong beaches and water plane in the Lake Superior basin. Geological Society of America Bulletin 52, 1935.Google Scholar
Stuiver, M., Reimer, P.J., Reimer, R.W., (2005). CALIB 6.0. WWW program and documentation. http://calib.qub.ac.uk/calib/ .Google Scholar
Teller, J.T., Leverington, D.W., (2004). Glacial Lake Agassiz; a 5000 yr history of change and its relationship to the delta (super 18) O record of Greenland. Geological Society of America Bulletin 116, 729742.Google Scholar
Teller, J.T., Thorleifson, L.H., (1983). The Lake Agassiz–Lake Superior connection. Teller, J.T., Clayton, L. Glacial Lake Agassiz. Geological Association of Canada special paper 26, 261290.Google Scholar
Thompson, T.A., Lepper, K., Endres, A.L., Johnston, J.W., Baedke, S.J., Argyilan, E.P., Booth, R.K., Wilcox, D.A., (2011). Mid Holocene lake level and shoreline behavior during the Nipissing phase of the upper Great Lakes at Alpena, Michigan, USA. Journal of Great Lakes Research 37, 567576.Google Scholar
Tinkler, K.J., Pengelly, J.W., (1995). Great Lakes response to catastrophic inflows from Lake Agassiz: some simulations of a hydraulic geometry for chained lake systems. Journal of Paleolimnology 13, 251266.Google Scholar
Tushingham, A.M., Peltier, W.R., (1991). Ice-3G: a new global model of late Pleistocene deglaciation based upon geophysical predictions of post-glacial relative sea level change. Journal of Geophysical Research 96, 4497.Google Scholar
Wright jr., H.E., Mattson, L.A., Thomas, J.A., (1970). Geology of the Cloquet quadrangle, Carlton County. Minnesota: Minnesota Geological Survey Geologic Map Series GM-3. Google Scholar
Yang, Z., Teller, J.T., (2012). Using LiDAR digital elevation model data to map Lake Agassiz beaches, measure their isostatically-induced slopes, and estimate their ages. Quaternary International 260, 3242.Google Scholar
Yu, S., Colman, S.M., Lowell, T.V., Milne, G.A., Fisher, T.G., Breckenridge, A., Boyd, M., Teller, J.T., (2010). Freshwater outburst from Lake Superior as a trigger for the cold event 9300 years ago. Science 328, 12621266.Google Scholar
Zoltai, S.C., (1965). Glacial features of the Quetico-Nipigon area, Ontario. Canadian Journal of Earth Sciences 2, 247269.Google Scholar
Zumberge, J.H., Gast, P., (1961). Geological investigations in Lake Superior. Geotimes 6, 1013.Google Scholar
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