Publication Date

2016

Document Type

Dissertation/Thesis

First Advisor

Dodd, Justin P.

Degree Name

M.S. (Master of Science)

Department

Department of Geology and Environmental Geosciences

LCSH

Ross Sea (Antarctica)--Environmental conditions|Glaciers--Antarctica--Ross Sea||Paleoclimatology--Antarctica--Ross Sea--Pliocene||Oxygen--Isotopes--Antarctica--Ross Sea

Abstract

Oxygen isotope measurements (δ¹⁸O) provide valuable insight into climate conditions. These data are advantageous as paleoclimate proxies, but records are sparse in high latitude waters, where calcareous microfossils are poorly preserved in marine sediments. Over glacial timescales, high latitude regions likely have the widest variability in terms of the δ¹⁸O values of marine waters; therefore, the paucity of data in these regions greatly hinders our ability to reconstruct global climatic and environmental change. This research is motivated to investigate Southern Ocean diatoms as a way to begin filling the gap in our knowledge. Diatoms are a cosmopolitan group of siliceous phytoplankton with characteristic ecological affinities. Diatom silica is increasingly being analyzed as a δ¹⁸O archive, and has the potential to provide comparable data to δ¹⁸O variations recorded by benthic foraminifera, but to date, studies have focused on Holocene sediments. This thesis presents oxygen isotope values from Early Pliocene Ross Sea diatoms, assessment of purification procedures, and implications for paleoclimate and the history of the West Antarctic Ice Sheet. ANDRILL AND-1B is a 13 Ma record from the Antarctic Geologic Drilling Project in the Ross Sea, which provides Lower to Mid Pliocene diatomite units. The context provided by age models and paleoenvironmental studies, along with more geologically recent Southern Ocean diatom δ¹⁸O measurements, make AND-1B an ideal dataset for further exploring the use of diatom δ¹⁸O values as a record of changes in salinity and temperature in high latitude seawater. Samples were purified; geochemically and mineralogically assessed using x-ray diffraction (e.g. identification of amorphous opal-A vs. mineral contamination) and x-ray fluorescence (e.g. elemental quantification of clay contamination); then analyzed for δ¹⁸O values using a step-wise fluorination (SWF) -- CO2 laser heating technique and a Thermo MAT 253 isotope ratio mass spectrometer. Correction methods based on different assumptions place constraints on true diatom δ¹⁸O values, with margins of error dependent on final sample purity. The results are intermediate between Holocene Antarctic diatom δ¹⁸O studies, indicating that diatom δ¹⁸O values can remain largely or entirely unaltered for at least 4.5 Ma. Interpreting these values through the current paleotemperature model, with the contingent paleoenvironmental constraints afforded by AND-1B, suggests water δ¹⁸O values offset about -10% relative to today's ocean. Stacked benthic foraminifera δ¹⁸O values for the Pliocene suggest an ocean average less than 1% different than the present; therefore, this points to a strong component of glacial water in a warmer, fresher Pliocene Ross Sea.

Comments

Advisors: Justin P. Dodd.||Committee members: Ross D. Powell; Reed P. Scherer.||Includes bibliographical references.||Includes illustrations and maps.

Extent

65 pages

Language

eng

Publisher

Northern Illinois University

Rights Statement

In Copyright

Rights Statement 2

NIU theses are protected by copyright. They may be viewed from Huskie Commons for any purpose, but reproduction or distribution in any format is prohibited without the written permission of the authors.

Media Type

Text

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