Constraining Circulation Changes Through the Last Deglaciation with Deep-sea Coral Radiocarbon and Sedimentary Pa231/Th230

Radioactive isotopes can be used in paleoceanography both for dating samples and as tracers of ocean processes. Here I use radiocarbon and uranium series isotopes to investigate the ocean's role in climate change over the last deglaciation. I present a new method for rapid radiocarbon analyses...

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Bibliographic Details
Main Author: Burke, Andrea
Other Authors: WOODS HOLE OCEANOGRAPHIC INSTITUTION MA
Format: Text
Language:English
Published: 2012
Subjects:
Isotopes
*CORAL
*ISOTOPES
*RADIOCARBON DATING
ANTARCTIC REGIONS
ATMOSPHERES
CARBON
CLIMATE
COMPUTATIONS
CONSISTENCY
CYCLES
DEEP OCEANS
GAS EXCHANGE(BIOLOGY)
GLACIERS
ICELAND
INVERSION
LOW TEMPERATURE
MASS
MODELS
NORTH ATLANTIC OCEAN
OCEANOGRAPHY
OCEANS
RADIOACTIVE ISOTOPES
RATES
RATIOS
SAMPLING
STRATIFICATION
SURVEYS
URANIUM
Antarctic
Drake Passage
Reykjanes
Southern Ocean
The Antarctic
Antarc*
Iceland
North Atlantic
Online Access:http://www.dtic.mil/docs/citations/ADA550599
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA550599
Description
Summary:Radioactive isotopes can be used in paleoceanography both for dating samples and as tracers of ocean processes. Here I use radiocarbon and uranium series isotopes to investigate the ocean's role in climate change over the last deglaciation. I present a new method for rapid radiocarbon analyses as a means of age-screening deep-sea corals for further study. Based on age survey results, I selected forty corals from the Drake Passage and thirteen from the Reykjanes Ridge off Iceland and dated them with uranium series isotopes. The uranium series dates give independent ages that allow radiocarbon to be used as a tracer of circulation and carbon cycle changes. The radiocarbon records generated from the Drake Passage corals show increased stratification in the Southern Ocean during the last glacial maximum (LGM) that disappeared during the start of the deglaciation as atmospheric CO2 began to rise during Heinrich Stadial 1 (H1). Considering these data and using a simple mass budget calculation, I show that the drop in atmospheric radiocarbon activity during H1 can be explained given direct carbon exchange between the radiocarbon-depleted deep ocean and atmosphere, e.g. through the Southern Ocean. The Drake Passage radiocarbon records also show evidence for decreased air-sea gas exchange in the Southern Ocean during the Antarctic Cold Reversal/B lling-Aller d coincident with the hiatus in the deglacial CO2 rise. During this time period in the North Atlantic, radiocarbon reconstructions from deep-sea corals collected from off Iceland show a similar ventilation rate to that observed today and during the Holocene. To further investigate changes in North Atlantic ventilation over the last deglaciation, I used an inverse model to assess the consistency of sedimentary 231Pa/230Th ratios from the Holocene, H1, and the LGM with the modern circulation. The original document contains color images.

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