Antarctic and Southern Ocean dust transport pathways: Forward-trajectory modeling and rare earth element source constraints from the RICE ice core

Mineral dust fertilization of Southern Ocean surface waters, and mixing with Antarctic deep-water, influences oceanic uptake of carbon dioxide and draws down global atmospheric concentrations during glacial periods. Quantifying modern variability in dust source and transport strength, especially wit...

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Bibliographic Details
Main Author: Neff, Peter David (11704814)
Format: Thesis
Language:unknown
Published: 2015
Subjects:
Geology not elsewhere classified
Ice core
Dust
Antarctica
School: School of Geography
Environment and Earth Sciences
040399 Geology not elsewhere classified
Degree Discipline: Geology
Degree Level: Doctoral
Degree Name: Doctor of Philosophy
Antarctic
Southern Ocean
Ross Sea
Patagonia
Pacific
New Zealand
Roosevelt Island
Antarc*
ice core
Online Access:https://doi.org/10.26686/wgtn.17012957.v1
id ftsmithonian:oai:figshare.com:article/17012957
record_format openpolar
institution Open Polar
collection Unknown
op_collection_id ftsmithonian
language unknown
topic Geology not elsewhere classified
Ice core
Dust
Antarctica
School: School of Geography
Environment and Earth Sciences
040399 Geology not elsewhere classified
Degree Discipline: Geology
Degree Level: Doctoral
Degree Name: Doctor of Philosophy
spellingShingle Geology not elsewhere classified
Ice core
Dust
Antarctica
School: School of Geography
Environment and Earth Sciences
040399 Geology not elsewhere classified
Degree Discipline: Geology
Degree Level: Doctoral
Degree Name: Doctor of Philosophy
Neff, Peter David (11704814)
Antarctic and Southern Ocean dust transport pathways: Forward-trajectory modeling and rare earth element source constraints from the RICE ice core
topic_facet Geology not elsewhere classified
Ice core
Dust
Antarctica
School: School of Geography
Environment and Earth Sciences
040399 Geology not elsewhere classified
Degree Discipline: Geology
Degree Level: Doctoral
Degree Name: Doctor of Philosophy
description Mineral dust fertilization of Southern Ocean surface waters, and mixing with Antarctic deep-water, influences oceanic uptake of carbon dioxide and draws down global atmospheric concentrations during glacial periods. Quantifying modern variability in dust source and transport strength, especially with respect to high- and low-latitude climate phenomena (e.g. the Southern Annular Mode, El Niño Southern Oscillation), will improve understanding of this important aspect of the global carbon cycle. Using high-order geochemical provenance techniques can also reveal in greater detail what aspects of dust transport are recorded in Antarctic ice core records, allowing for better interpretation of glacial-interglacial dust records at individual sites. First, using forward trajectories and climate reanalysis data, this work explores modern variability (1979-2013) in atmospheric transport of mineral dust from Southern Hemisphere potential source areas (PSA)—primarily Australia, southern South America and southern Africa. Estimates of the relative source and transport strength of New Zealand are also discussed, and compared with other dust PSA to evaluate New Zealand’s potential contribution to Southern Ocean and Antarctic dust deposition. Extra-Antarctic dust PSA distributions are detailed for individual ice core sites, including the newly recovered Roosevelt Island Climate Evolution (RICE) ice core (79.36ºS, 161.71ºW, 550 m a.s.l.). This approach—applicable to many types of aerosol—reveals persistent, strong transport from New Zealand and Patagonia to the southern high-latitudes during all seasons. It also demonstrates that southward transport of air masses from pan-Pacific dust sources is affected by circulation variability initiated in the central tropical Pacific Ocean. High-resolution discrete sampling of the RICE core allows for unprecedented analysis of trace elements at sub-annual to annual scales. The rare earth elements (REE, lanthanide elements Lanthanum to Lutetium) can preserve the signature of their original source material and thus provide provenance constraints for dust preserved in Antarctic snow and ice. While challenging, measurements of REE concentration to the single femtogram per gram (10-15 g g-1) level have been made by combining efficient sample introduction and a jet-interface sector-field inductively coupled plasma mass spectrometer. The methodology and fidelity of these measurements are presented, in addition to results for other low-concentration elements associated with natural and anthropogenic aerosols. REE data from the RICE ice core are then used to explore possible modern sources of dust in the Ross Sea sector of Antarctica, testing hypothesized trajectory model distributions. Twentieth-century and late-Holocene (2.3 ka – present) REE data from the RICE ice core represent the first measurements of this kind from the Pacific sector of Antarctica. RICE data are compared with Holocene REE data from the Drønning Maud Land and Dome C ice cores, with consideration of REE signatures in dust samples from PSA. Data from the RICE ice core indicate fewer than 5% contributions of dust from South America, and show strong negative trends in crustal-normalized REE signatures suggesting contributions from local Antarctic dust.
format Thesis
author Neff, Peter David (11704814)
author_facet Neff, Peter David (11704814)
author_sort Neff, Peter David (11704814)
title Antarctic and Southern Ocean dust transport pathways: Forward-trajectory modeling and rare earth element source constraints from the RICE ice core
title_short Antarctic and Southern Ocean dust transport pathways: Forward-trajectory modeling and rare earth element source constraints from the RICE ice core
title_full Antarctic and Southern Ocean dust transport pathways: Forward-trajectory modeling and rare earth element source constraints from the RICE ice core
title_fullStr Antarctic and Southern Ocean dust transport pathways: Forward-trajectory modeling and rare earth element source constraints from the RICE ice core
title_full_unstemmed Antarctic and Southern Ocean dust transport pathways: Forward-trajectory modeling and rare earth element source constraints from the RICE ice core
title_sort antarctic and southern ocean dust transport pathways: forward-trajectory modeling and rare earth element source constraints from the rice ice core
publishDate 2015
url https://doi.org/10.26686/wgtn.17012957.v1
long_lat ENVELOPE(-162.000,-162.000,-79.283,-79.283)
geographic Antarctic
Southern Ocean
Ross Sea
Patagonia
Pacific
New Zealand
Roosevelt Island
geographic_facet Antarctic
Southern Ocean
Ross Sea
Patagonia
Pacific
New Zealand
Roosevelt Island
genre Antarc*
Antarctic
Antarctica
ice core
Roosevelt Island
Ross Sea
Southern Ocean
genre_facet Antarc*
Antarctic
Antarctica
ice core
Roosevelt Island
Ross Sea
Southern Ocean
op_relation https://figshare.com/articles/thesis/Antarctic_and_Southern_Ocean_dust_transport_pathways_Forward-trajectory_modeling_and_rare_earth_element_source_constraints_from_the_RICE_ice_core/17012957
doi:10.26686/wgtn.17012957.v1
op_rights Author Retains Copyright
op_doi https://doi.org/10.26686/wgtn.17012957.v1
_version_ 1766096802416689152
spelling ftsmithonian:oai:figshare.com:article/17012957 2023-05-15T13:37:42+02:00 Antarctic and Southern Ocean dust transport pathways: Forward-trajectory modeling and rare earth element source constraints from the RICE ice core Neff, Peter David (11704814) 2015-01-01T00:00:00Z https://doi.org/10.26686/wgtn.17012957.v1 unknown https://figshare.com/articles/thesis/Antarctic_and_Southern_Ocean_dust_transport_pathways_Forward-trajectory_modeling_and_rare_earth_element_source_constraints_from_the_RICE_ice_core/17012957 doi:10.26686/wgtn.17012957.v1 Author Retains Copyright Geology not elsewhere classified Ice core Dust Antarctica School: School of Geography Environment and Earth Sciences 040399 Geology not elsewhere classified Degree Discipline: Geology Degree Level: Doctoral Degree Name: Doctor of Philosophy Text Thesis 2015 ftsmithonian https://doi.org/10.26686/wgtn.17012957.v1 2021-12-19T21:50:03Z Mineral dust fertilization of Southern Ocean surface waters, and mixing with Antarctic deep-water, influences oceanic uptake of carbon dioxide and draws down global atmospheric concentrations during glacial periods. Quantifying modern variability in dust source and transport strength, especially with respect to high- and low-latitude climate phenomena (e.g. the Southern Annular Mode, El Niño Southern Oscillation), will improve understanding of this important aspect of the global carbon cycle. Using high-order geochemical provenance techniques can also reveal in greater detail what aspects of dust transport are recorded in Antarctic ice core records, allowing for better interpretation of glacial-interglacial dust records at individual sites. First, using forward trajectories and climate reanalysis data, this work explores modern variability (1979-2013) in atmospheric transport of mineral dust from Southern Hemisphere potential source areas (PSA)—primarily Australia, southern South America and southern Africa. Estimates of the relative source and transport strength of New Zealand are also discussed, and compared with other dust PSA to evaluate New Zealand’s potential contribution to Southern Ocean and Antarctic dust deposition. Extra-Antarctic dust PSA distributions are detailed for individual ice core sites, including the newly recovered Roosevelt Island Climate Evolution (RICE) ice core (79.36ºS, 161.71ºW, 550 m a.s.l.). This approach—applicable to many types of aerosol—reveals persistent, strong transport from New Zealand and Patagonia to the southern high-latitudes during all seasons. It also demonstrates that southward transport of air masses from pan-Pacific dust sources is affected by circulation variability initiated in the central tropical Pacific Ocean. High-resolution discrete sampling of the RICE core allows for unprecedented analysis of trace elements at sub-annual to annual scales. The rare earth elements (REE, lanthanide elements Lanthanum to Lutetium) can preserve the signature of their original source material and thus provide provenance constraints for dust preserved in Antarctic snow and ice. While challenging, measurements of REE concentration to the single femtogram per gram (10-15 g g-1) level have been made by combining efficient sample introduction and a jet-interface sector-field inductively coupled plasma mass spectrometer. The methodology and fidelity of these measurements are presented, in addition to results for other low-concentration elements associated with natural and anthropogenic aerosols. REE data from the RICE ice core are then used to explore possible modern sources of dust in the Ross Sea sector of Antarctica, testing hypothesized trajectory model distributions. Twentieth-century and late-Holocene (2.3 ka – present) REE data from the RICE ice core represent the first measurements of this kind from the Pacific sector of Antarctica. RICE data are compared with Holocene REE data from the Drønning Maud Land and Dome C ice cores, with consideration of REE signatures in dust samples from PSA. Data from the RICE ice core indicate fewer than 5% contributions of dust from South America, and show strong negative trends in crustal-normalized REE signatures suggesting contributions from local Antarctic dust. Thesis Antarc* Antarctic Antarctica ice core Roosevelt Island Ross Sea Southern Ocean Unknown Antarctic Southern Ocean Ross Sea Patagonia Pacific New Zealand Roosevelt Island ENVELOPE(-162.000,-162.000,-79.283,-79.283)

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