Orbital-scale controls on biogenic silica accumulation in the Indian Sector of the Southern Ocean over the past 600,000 years

Variations in Earth’s orbital geometry and relative location to the Sun have influenced climate throughout geologic time. These cycles include orbital eccentricity, obliquity, and precession. Combined, these parameters influence the distribution of radiative forcing received by each latitude on Eart...

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Bibliographic Details
Main Author: Kaiser, Emily Ann
Format: Thesis
Language:English
Published: University of Delaware 2020
Subjects:
Biogenic silica
Orbital-scale
Paleoceanography
Pleistocene
Southern Ocean
Stratification
Antarctic
Indian
Antarc*
Online Access:https://udspace.udel.edu/handle/19716/28347
Description
Summary:Variations in Earth’s orbital geometry and relative location to the Sun have influenced climate throughout geologic time. These cycles include orbital eccentricity, obliquity, and precession. Combined, these parameters influence the distribution of radiative forcing received by each latitude on Earth (insolation), which has been linked to climate warming and cooling. Records of climate, such as oxygen isotopes, display variations in concert with the amount of radiative forcing received by Earth. Another factor that plays into glacial/interglacial climate is the amount of greenhouse gases in the atmosphere. Previous studies, utilizing ice cores, have revealed that the concentrations of greenhouse gas, such as carbon dioxide, in the atmosphere vary over glacial/interglacial timescales. One hypothesis to explain the difference between low glacial CO2 and high interglacial CO2 relies on stratification within the Southern Ocean (e.g., Sigman & Boyle, 2000). In this study, I hypothesize that atmospheric CO2 levels are regulated by changes in Southern Ocean stratification. For example, interglacial climates have high atmospheric CO2 levels due to a well-ventilated Southern Ocean. Within the modern Antarctic Zone of the Southern Ocean, nutrient- rich deep waters are pulled to the surface via Ekman pumping (upwelling), fueling one of the most biologically productive regions of the world’s oceans. These deepwater masses that are upwelled also contain dissolved CO2. On glacial/interglacial timescales, Southern Ocean stratification has been linked to global climate change as a mechanism that regulates atmospheric CO2 levels. ☐ Downcore variations in opal production are generally used as a proxy for upwelling throughout geologic time. Typically, these records are restricted to the past glacial/interglacial cycle due to the vast ability of sedimentological records spanning recent geologic time. In this study, I expand understanding of Southern Ocean stratification, evidenced by changes in upwelling, over the past 600 kyr ...

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