Lifting the Champlain Sea: A CAS Record of the Transition to Modern Lake Champlain

Between about 9 and 13 ky bp, the isostatically depressed area of the Champlain, Ottawa and St Lawrence valleys were engulfed by the Atlantic Ocean. The resulting Champlain Sea had two distinct sources of water: fresh water sourced from large proglacial lakes fed by the collapsing Laurentide Ice She...

Full description

Bibliographic Details
Main Author: Robinson, Andrew
Other Authors: Lyons, Timothy
Format: Other/Unknown Material
Language:English
Published: eScholarship, University of California 2012
Subjects:
Geology
Geochemistry
CAS
Champlain
sulfate
Ice Sheet
North Atlantic
Online Access:https://escholarship.org/uc/item/1nt7c3s2
id ftcdlib:oai:escholarship.org/ark:/13030/qt1nt7c3s2
record_format openpolar
spelling ftcdlib:oai:escholarship.org/ark:/13030/qt1nt7c3s2 2023-05-15T16:41:38+02:00 Lifting the Champlain Sea: A CAS Record of the Transition to Modern Lake Champlain Robinson, Andrew Lyons, Timothy 2012-01-01 application/pdf https://escholarship.org/uc/item/1nt7c3s2 en eng eScholarship, University of California qt1nt7c3s2 https://escholarship.org/uc/item/1nt7c3s2 public Geology Geochemistry CAS Champlain sulfate etd 2012 ftcdlib 2020-06-06T07:56:52Z Between about 9 and 13 ky bp, the isostatically depressed area of the Champlain, Ottawa and St Lawrence valleys were engulfed by the Atlantic Ocean. The resulting Champlain Sea had two distinct sources of water: fresh water sourced from large proglacial lakes fed by the collapsing Laurentide Ice Sheet and North Atlantic marine waters sourced via the contemporaneous eustatic rise. This study focuses on the most recent transition from the Champlain Sea (CS) to modern Lake Champlain when the fluxes between the two water sources were in a state of transition. Carbonate-associated sulfate (CAS) offers proxy evidence for the δ34S of ancient waters, a key piece in our interpretation of both flux dynamics and primary redox conditions within the basin. Previous research into CAS has shown that sulfate can be structurally substituted into authigenic and biogenic carbonates. Following wide ranging efforts to calibrate and validate this proxy, it has been demonstrated that the isotopic composition commonly reflects the ambient waters at the time of carbonate precipitation. Because of relatively low rates of bacterial sulfate reduction, the δ34S of CAS in the restricted CS can be used to approximate salinity relationships over the interval of interest. These data suggest the Champlain Sea was subject to four flood events from Lake Agassiz dropping salinity (measured in Practical Salinity Units) throughout the lifetime of the marine incursion. Splits taken from the CAS solution yield Mg, Fe, & Sr concentrations; unique to each water source, these data reflect the marine to lacustrine change in aqueous metals and identify the source of the proglacial flood source as Lake Agassiz. Due to the low concentrations of both CAS and calcium carbonate in our samples, we are in a unique position to assess the lower limits of the CAS proxys utility in studies of marine to lacustrine transitions. By capturing the transition from the Champlain Sea to Lake Champlain I detail the dynamics of this evolution as both unrelenting isostatic rebounding and diminishing flood sizes repeatedly lowered the salinity (PSU) of the CS. Moreover, low pyrite and iron monosulfide concentrations within the sediments reveal that aqueous sulfate must have been delivered back into the North Atlantic. Other/Unknown Material Ice Sheet North Atlantic University of California: eScholarship
institution Open Polar
collection University of California: eScholarship
op_collection_id ftcdlib
language English
topic Geology
Geochemistry
CAS
Champlain
sulfate
spellingShingle Geology
Geochemistry
CAS
Champlain
sulfate
Robinson, Andrew
Lifting the Champlain Sea: A CAS Record of the Transition to Modern Lake Champlain
topic_facet Geology
Geochemistry
CAS
Champlain
sulfate
description Between about 9 and 13 ky bp, the isostatically depressed area of the Champlain, Ottawa and St Lawrence valleys were engulfed by the Atlantic Ocean. The resulting Champlain Sea had two distinct sources of water: fresh water sourced from large proglacial lakes fed by the collapsing Laurentide Ice Sheet and North Atlantic marine waters sourced via the contemporaneous eustatic rise. This study focuses on the most recent transition from the Champlain Sea (CS) to modern Lake Champlain when the fluxes between the two water sources were in a state of transition. Carbonate-associated sulfate (CAS) offers proxy evidence for the δ34S of ancient waters, a key piece in our interpretation of both flux dynamics and primary redox conditions within the basin. Previous research into CAS has shown that sulfate can be structurally substituted into authigenic and biogenic carbonates. Following wide ranging efforts to calibrate and validate this proxy, it has been demonstrated that the isotopic composition commonly reflects the ambient waters at the time of carbonate precipitation. Because of relatively low rates of bacterial sulfate reduction, the δ34S of CAS in the restricted CS can be used to approximate salinity relationships over the interval of interest. These data suggest the Champlain Sea was subject to four flood events from Lake Agassiz dropping salinity (measured in Practical Salinity Units) throughout the lifetime of the marine incursion. Splits taken from the CAS solution yield Mg, Fe, & Sr concentrations; unique to each water source, these data reflect the marine to lacustrine change in aqueous metals and identify the source of the proglacial flood source as Lake Agassiz. Due to the low concentrations of both CAS and calcium carbonate in our samples, we are in a unique position to assess the lower limits of the CAS proxys utility in studies of marine to lacustrine transitions. By capturing the transition from the Champlain Sea to Lake Champlain I detail the dynamics of this evolution as both unrelenting isostatic rebounding and diminishing flood sizes repeatedly lowered the salinity (PSU) of the CS. Moreover, low pyrite and iron monosulfide concentrations within the sediments reveal that aqueous sulfate must have been delivered back into the North Atlantic.
author2 Lyons, Timothy
format Other/Unknown Material
author Robinson, Andrew
author_facet Robinson, Andrew
author_sort Robinson, Andrew
title Lifting the Champlain Sea: A CAS Record of the Transition to Modern Lake Champlain
title_short Lifting the Champlain Sea: A CAS Record of the Transition to Modern Lake Champlain
title_full Lifting the Champlain Sea: A CAS Record of the Transition to Modern Lake Champlain
title_fullStr Lifting the Champlain Sea: A CAS Record of the Transition to Modern Lake Champlain
title_full_unstemmed Lifting the Champlain Sea: A CAS Record of the Transition to Modern Lake Champlain
title_sort lifting the champlain sea: a cas record of the transition to modern lake champlain
publisher eScholarship, University of California
publishDate 2012
url https://escholarship.org/uc/item/1nt7c3s2
genre Ice Sheet
North Atlantic
genre_facet Ice Sheet
North Atlantic
op_relation qt1nt7c3s2
https://escholarship.org/uc/item/1nt7c3s2
op_rights public
_version_ 1766032093074161664

Similar Items