High-resolution seismic stratigraphy of Late Pleistocene Glacial Lake Iroquois and its Holocene successor: Oneida Lake, New York

Nicholas J. Zaremba, Christopher A. Scholz

Research output: Contribution to journalArticlepeer-review

7 Scopus citations

Abstract

Oneida Lake, New York, is the remnant of Glacial Lake Iroquois, a large proglacial lake that delivered fresh water to the Atlantic Ocean during the last deglaciation. The formation of Glacial Lake Iroquois and its subsequent drainage into the Atlantic Ocean via the Mohawk Valley was a significant shift in the routing of Laurentide Ice Sheet meltwater to the east instead of south via the Allegheny or Susquehanna Rivers. Catastrophic drainage of Glacial Lake Iroquois into the Atlantic Ocean via the Champlain Valley is interpreted as the meltwater pulse responsible for the Intra-Allerod cold stadial. Therefore, understanding the evolution of Glacial Lake Iroquois has significant implications for understanding late Pleistocene paleoclimate. High-resolution CHIRP seismic reflection data provides insight into the evolution of Glacial Lake Iroquois and Oneida Lake. Three seismic units image distinct stages of the Oneida Basin. Unit 1 is interpreted as proglacial lake deposits that overlie glacial till. Unit 2 is interpreted as sediments deposited when the Oneida Basin became isolated from Glacial Lake Iroquois and Unit 3 is interpreted as lacustrine sediments of the modern lake. Distally sourced turbidites possibly triggered by seismic activity or ice sheet meltwater pulses are represented as reflection-free acoustic facies that infill topographic lows and range in thickness from ~1–5 m within otherwise conformable proglacial lake deposits. Local slump deposits imaged at the boundary between Unit 1 and 2 were likely triggered by the drainage of Glacial Lake Iroquois. Wave cut terraces indicative of a low stand on the upper bounding surface of Unit 2 are likely the result of drier conditions during the Holocene Hypsithermal. Furthermore, preservation of this low stand suggests a rapid rise in lake level, possibly the result of the same transition to a wetter climate responsible for the Nipissing transgression observed in the Laurentian Great lakes.

Original languageEnglish (US)
Article number109286
JournalPalaeogeography, Palaeoclimatology, Palaeoecology
Volume534
DOIs
StatePublished - Nov 15 2019

Bibliographical note

Funding Information:
Support for this research was provided by the National Science Foundation Paleo Perspectives on Climate Change program ( P2C2 ), through NSF/EAR grant 1804460 to CAS.

Funding Information:
Support for this research was provided by the U.S. National Science Foundation Paleo Perspectives on Climate Change program (P2C2), through NSF/EAR grant 1804460 to CAS. We thank B. Bird and A. Kozlowski for sharing shape files of the shoreline of Glacial Lake Iroquois and Laurentide Ice Sheet margin; Hamilton College for use of their research vessel; B. Wetger, D.A. Wood, L. Wright, J. Corbett, and M. Tan for assistance during field work. Seismic analysis was carried out using Landmark Graphics Corporation DecisionSpace software, provided on a software grant to CAS. J. Ridge, A. Leventer, and B. Rosenheim provided constructive assistance in various phases of the project. We thank the late Eugene W. Domack for his creativity, energy and insights.

Publisher Copyright:
© 2019 Elsevier B.V.

Copyright:
Copyright 2019 Elsevier B.V., All rights reserved.

Keywords

  • Holocene Hypsithermal
  • Intra-Allerod
  • Laurentide ice sheet
  • Meltwater pulse
  • Mohawk Valley
  • Proglacial lake deposits

Continental Scientific Drilling Facility tags

  • ONEIDA

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