Abstract
Glacial Lake Agassiz, the largest of the North American glacial lakes, discharged through several different outlets during its history, although the timing and location of discharge remain controversial. However, one discharge event is well established based on extensive onshore observations: drainage through the Nipigon Lake area into the Superior basin about 10,700 years ago, following retreat of ice of the Marquette advance from the basin. High-resolution, single-channel seismic-reflection data collected with a small airgun were acquired to test the hypothesis that the Post-Marquette drainage event left diagnostic stratigraphic and geomorphic signatures beneath Lake Superior. The unique bathymetry of northwestern Lake Superior, where water depth plunges off Nipigon and Black Bays, makes this location ideal for the characterization of the post-Marquette depositional and erosional features. According to our hypothesis, the initial, sudden discharge of high-velocity water would have eroded channels through the bays. The steep and sudden drop-off into the Superior basin would have caused the flow to slow and drop much of the sediment it was carrying. Our results confirm the existence of both erosional features and depositional sediment packages related to Lake Agassiz discharge at this time. The erosional features include deeply incised bedrock channels in the bays. The depositional features comprise subaqueous fans that are thickest in the deep water areas adjacent to the outlets and thin lakeward and laterally away from the channels. The seismic character of the basal units of the fans, proximal to the channels, is chaotic and only very weakly stratified, suggesting that these deposits represent coarse sediment laid down during the initial, high-energy stages of the flood. These sediments are overlain by a stratified package which is interpreted as the fine grained sediment associated with the later, low-energy stages of the flood. The combination of channels and subaqueous fans is inferred to be diagnostic of high-energy Lake Agassiz discharge into the Superior basin, and they serve as analogs for hypothesized discharge at other times.
Original language | English (US) |
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Pages (from-to) | 299-311 |
Number of pages | 13 |
Journal | Journal of Paleolimnology |
Volume | 47 |
Issue number | 3 |
DOIs | |
State | Published - Mar 2012 |
Bibliographical note
Funding Information:Acknowledgments The authors would like to thank Jim Teller, Matt Boyd, Andy Breckenridge, and Carrie Jennings for helpful discussions of this project. We would also like to thank the captain and crew of the R.V. Blue Heron. This work was supported by National Science Foundation grant OCE-0623607 to Colman and Wattrus.
Keywords
- Glacial Lake Agassiz
- Glacial geology
- Lake Superior
- Seismic-reflection data
- Stratigraphy