Hostname: page-component-586b7cd67f-dsjbd Total loading time: 0 Render date: 2024-11-20T11:30:31.419Z Has data issue: false hasContentIssue false

Sedimentary architecture of the southern basin of Lake of the Woods, Minnesota and its relation to Lake Agassiz history and Holocene environmental change

Published online by Cambridge University Press:  10 April 2018

Devin D. Hougardy
Affiliation:
Large Lakes Observatory, University of Minnesota Duluth, Duluth, Minnesota 55812 Department of Earth and Environmental Sciences, University of Minnesota Duluth, Duluth, Minnesota, 55812
Steven M. Colman*
Affiliation:
Large Lakes Observatory, University of Minnesota Duluth, Duluth, Minnesota 55812
*
* Corresponding author: E-mail address: [email protected] (S.M. Colman).

Abstract

Lake of the Woods (LOTW) is a large, complex lake basin once occupied by glacial Lake Agassiz. High-resolution seismic-reflection profiles and cores in the shallow, open southern basin of LOTW reveal a sedimentary architecture comprising four lacustrine units separated by three low-stand unconformities. These units represent several phases of Lake Agassiz and its changing configuration. One unconformity marks the Moorhead low phase and another marks the separation of LOTW from Lake Agassiz, perhaps ~10 cal ka BP, as the level of the latter fell, but before final drainage of Agassiz. Initially, the separate Holocene lake in the southern basin was broad and shallow, sometimes marshy or dry. Shortly after 8 cal ka BP, the southern basin dried up completely, despite the progressive rise of the northern outlet of the lake due to differential isostatic uplift. The resulting hiatus is related to the well-documented mid-Holocene arid interval in central North America. A return to wetter conditions in the late Holocene caused the southern basin of LOTW to refill since about 3800 cal yr BP. Late Holocene sediments have accumulated slightly asymmetrically in the basin, possible due to continued southward transgression of the lake as a result of isostatic tilting.

Type
Research Article
Copyright
Copyright © University of Washington. Published by Cambridge University Press, 2018 

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

REFERENCES

Bajc, A.F., Schwert, D.P., Warner, B.G., Williams, N.E., 2000. A reconstruction of Moorhead and Emerson phase environments along the eastern margin of glacial Lake Agassiz, Rainy River basin, northwestern Ontario. Canadian Journal of Earth Sciences 37, 13351353.Google Scholar
Barber, D.C., Dyke, A., Hillaire-Marcel, C., Jennings, A.E., Andrews, J.T., Kerwin, M.W., Bilodeau, G., et al., 1999. Forcing of the cold event of 8,200 years ago by catastrophic drainage of Laurentide lakes. Nature 400, 344348.CrossRefGoogle Scholar
Bradbury, J.P., Dean, W.E., Anderson, R.Y., 1993. Holocene climatic and limnologic history of the north-central United States as recorded in the varved sediments of Elk Lake, Minnesota: a synthesis. In: Bradbury, J.P., Dean, W.E. (Eds.), Elk Lake, Minnesota: Evidence for Rapid Climate Change in the North-Central United States. Geological Society of America Special Paper 276. Geological Society of America, Boulder, pp. 309328.Google Scholar
Breckenridge, A., 2015. The Tintah-Campbell gap and implications for glacial Lake Agassiz drainage during the Younger Dryas cold interval. Quaternary Science Reviews 117, 124134.CrossRefGoogle Scholar
Clayton, L., 1983. Chronology of Lake Agassiz drainage to Lake Superior. In: Teller, J.T., Clayton, L. (Eds.), Glacial Lake Agassiz. Geological Association of Canada Special Paper 26, Geological Association of Canada, St. Johns, Newfoundland, pp. 291307.Google Scholar
* COHMAP, 1988. Climatic changes of the last 18,000 years: observations and model simulations. Science 241, 10431052.CrossRefGoogle Scholar
Colman, S.M., Brown, E.T., Rush, R.A., 2012. Mid-Holocene drought and lake-level change at Elk Lake, Clearwater County, Minnesota: evidence from CHIRP seismic-reflection data. The Holocene 23, 460465.Google Scholar
Colman, S.M., Jones, G.A., Rubin, M., King, J.W., Peck, J.A., Orem, W.H., 1996. AMS radiocarbon analyses from Lake Baikal, Siberia: challenges of dating sediments from a large, oligotrophic lake. Quaternary Geochronology (Quaternary Science Reviews) 15, 669684.Google Scholar
Dean, W.E., Forester, R.M., Bradbury, J.P., 2002. Early Holocene change in atmospheric circulation in the Northern Great Plains: an upstream view of the 8.2 ka cold event. Quaternary Science Reviews 21, 17631775.CrossRefGoogle Scholar
Elson, J.A., 1967. Geology of glacial Lake Agassiz. In: Mayer-Oakes, W.J. (Ed.), Life, Land and Water - Proceedings of the 1966 Conference on Environmental Studies of the Glacial Lake Agassiz Region. Publisher, Winnipeg, pp. 37–96.Google Scholar
Fenton, M.M., Moran, S.R., Teller, J.T., Clayton, L., 1983. Quaternary stratigraphy and history in the southern part of the Lake Agassiz basin. In: Teller, J.T., Clayton, L. (Eds.), Glacial Lake Agassiz. Geological Association Canada, Special Paper 26, Geological Association of Canada, St. Johns, Newfoundland, pp. 4974.Google Scholar
Fisher, T.G., Lepper, K., Ashworth, A.C., Hobbs, H.C., 2011. Southern outlet and basin of glacial Lake Agassiz. In: Miller, J.D., Hudak, G.J., Wittkop, C., McLaughlin, P.I. (Eds.), Field Guides to the Geology of the Mid-Continent of North America: Geological Society of America Field Guide 24. Geological Society of America, Boulder, pp. 379400.Google Scholar
Fisher, T.G., Yansa, C.H., Lowell, T.V., Lepper, K., Hajdas, I., Ashworth, A., 2008. The chronology, climate, and confusion of the Moorhead Phase of glacial Lake Agassiz: new results from the Ojata Beach, North Dakota, USA. Quaternary Science Reviews 27, 11241135.Google Scholar
Grimm, E.C., Donovan, J.J., Brown, K.J., 2011. A high-resolution record of climate variability and landscape response from Kettle Lake, northern Great Plains, North America. Quaternary Science Reviews 30, 26262650.CrossRefGoogle Scholar
Hougardy, D.D., 2013. The Geologic History of Lake of the Woods, Minnesota, Reconstructed Using Seismic-Reflection Imaging and Sediment Core Analysis. Master’s thesis, University of Minnesota, Duluth.Google Scholar
Hu, F.S., Slawinski, D., Wright, H.E.J., Ito, E., Johnson, R.G., Kelts, K.R., McEwan, R.F., Boedigheimer, A., 1999. Abrupt changes in North American climate during early Holocene times. Nature 400, 437440.Google 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, 20.Google Scholar
Kelly, M.A., Fisher, T.G., Lowell, T.V., Barnett, P.J., Schwartz, R., Gajewski, K., 2016. 10Be ages of flood deposits west of Lake Nipigon, Ontario: evidence for eastward meltwater drainage during the early Holocene Epoch. Canadian Journal of Earth Sciences 53, 321330.Google Scholar
Lepper, K., Buell, A.W., Fisher, T.G., Lowell, T.V., 2013. A chronology for glacial Lake Agassiz shorelines along Upham’s namesake transect. Quaternary Research 80, 8898.Google Scholar
Lepper, K., Fisher, T.G., Hajdas, I., Lowell, T.V., 2007. Ages for the Big Stone Moraine and the oldest beaches of glacial Lake Agassiz: implications for deglaciation chronology. Geology 35, 667670.Google Scholar
Lepper, K., Gorz, K.L., Fisher, T.G., Lowell, T.V., 2011. Age determinations for glacial Lake Agassiz shorelines west of Fargo, North Dakota, USA. Canadian Journal of Earth Sciences 48, 11991207.Google Scholar
Lewis, C., King, J., Blasco, S., Brooks, G., Coakley, J., Croley, I.T.E., Dettman, D., et al., 2008. Dry climate disconnected the Laurentian Great Lakes. EOS, Transactions of the American Geophysical Union 89, 541542.Google Scholar
Lowell, T., Waterson, N., Fisher, T., Loop, H., Glover, K., Comer, G., Hajdas, I., et al., 2005. Testing the Lake Agassiz meltwater trigger for the Younger Dryas. EOS, Transactions of the American Geophysical Union 86, 365373.Google Scholar
Lowell, T.V., Applegate, P.J., Fisher, T.G., Lepper, K., 2013. What caused the low-water phase of glacial Lake Agassiz? Quaternary Research 80, 370382.Google Scholar
Mellors, T., 2010. Holocene paleohydrology from Lake of the Woods and Shoal Lake cores using ostracodes, thecamoebians, and sediment properties. Master’s thesis, University of Manitoba, Winnipeg.Google Scholar
Myrbo, A., Wright, H.E., 2008. The Livingstone/Bolivia SOP. Limnological Research Center Core Facility SOP Series 3.1, 1–12.Google Scholar
Reimer, P.J., Bard, E., Bayliss, A., Beck, J.W., Blackwell, P.G., Ramsey, C.B., Buck, C.E., et al., 2013. Intcal13 and marine13 radiocarbon age calibration curves 0–50,000 years cal bp. Radiocarbon 55, 18691887.CrossRefGoogle Scholar
Schnurrenberger, D., Russell, J., Kelts, K., 2003. Classification of lacustrine sediments based on sedimentary components. Journal of Paleolimnology 29, 141154.CrossRefGoogle Scholar
Stoker, M.S., Pheasant, J.B., Josenhans, H., 1997. Seismic methods and interpretation. In: Davies, T.A., Bell, T., Cooper, A.K., Josenhans, H., Polyak, L., Solheim, A., Stoker, M.S., Stravers, J.A. (Eds.), Glaciated Continental Margins: An Atlas of Acoustic Images. Springer, Dordrecht, p. 922.Google Scholar
Stuiver, M., Reimer, P.J., 1986. A computer-program for radiocarbon age calibration. Radiocarbon 28, 10221030.CrossRefGoogle Scholar
Teller, J.T., 1995. History and drainage of large ice-dammed lakes along the Laurentide Ice Sheet. Quaternary International 28, 8392.CrossRefGoogle Scholar
Teller, J.T., 2013. Lake Agassiz during the Younger Dryas. Quaternary Research 80, 361369.Google Scholar
Teller, J.T., Clayton, L., 1983. Glacial Lake Agassiz. Geological Association of Canada Special Paper 26, Geological Association of Canada, St. Johns, Newfoundland, 451 p.Google Scholar
Teller, J.T., Leverington, D.W., 2004. Glacial Lake Agassiz: a 5000 yr history of change and its relationship to the d18O record of Greenland. Geological Society of America Bulletin 116, 729742.Google Scholar
Teller, J.T., Ruhland, K.M., Smol, J.P., Mellors, T.J., Paterson, A.M., 2018. Holocene history of Lake of the Woods: Ontario, Manitoba, and Minnesota. Geological Society of America Bulletin 130, 323.Google Scholar
Teller, J.T., Thorleifson, L.H., 1983. The Lake Agassiz–Lake Superior connection. In: Teller, J.T., Clayton, L. (Ed.), Glacial Lake Agassiz. Geological Association Canada Special Paper 26, Geological Association of Canada, St. Johns, Newfoundland, pp. 261290.Google Scholar
Teller, J.T., Yang, Z., Boyd, M., Buhay, W.M., McMillan, K., Kling, H.J., Telka, A.M., 2008. Postglacial sedimentary record and history of West Hawk Lake crater, Manitoba. Journal of Paleolimnology 40, 661688.Google Scholar
Todd, B.J., Lewis, C.F.M., Nielsen, E., Thorleifson, L.H., Bezys, R.K., Weber, W., 1998. Lake Winnipeg: geological setting and sediment seismostratigraphy. Journal of Paleolimnology 19, 215244.Google Scholar
Upham, W., 1895. The Glacial Lake Agassiz. United States Geological Survey Monograph 25, U.S. Geological Survey, Washington, 658 p.CrossRefGoogle Scholar
Williams, J.W., Shuman, B., Bartlein, P.J., Diffenbaugh, N.S., Webb, T., 2010. Rapid, time-transgressive, and variable responses to early Holocene midcontinental drying in North America. Geology 38, 135138.CrossRefGoogle Scholar
Yang, Z.R., Teller, J.T., 2005. Modeling the history of Lake of the Woods since 11,000 cal yr BP using GIS. Journal of Paleolimnology 33, 483498.CrossRefGoogle Scholar
Supplementary material: File

Hougardy and Colman supplementary material 1

Supplementary Table

Download Hougardy and Colman supplementary material 1(File)
File 10.3 MB