Insight to forcing of late Quaternary climate change from aeolian dust archives in eastern Australia

The Australian continent is the largest source of dust in the Southern Hemisphere. Historical dust emissions records display inter-annual variability in response to the El Niño Southern Oscillation (ENSO) phenomenon and inter-decadal variability which has been linked to the Pacific Decadal Oscillati...

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Main Authors: McGowan, H A, Marx, S K, Soderholm, J, Denholm, J, Petherick, L
Format: Conference Object
Language:English
Published: American Geophysical Union 2010
Subjects:
FoR 0406 (Physical Geography and Environmental Geoscience)
climate change
Quaternary
Greenland
Pacific
Queensland
Antarc*
Antarctica
ice core
North Atlantic
Online Access:http://www.agu.org/meetings/fm10/
id ftunivscoast:usc:6698
record_format openpolar
spelling ftunivscoast:usc:6698 2023-05-15T13:56:25+02:00 Insight to forcing of late Quaternary climate change from aeolian dust archives in eastern Australia McGowan, H A Marx, S K Soderholm, J Denholm, J Petherick, L 2010 http://www.agu.org/meetings/fm10/ eng eng American Geophysical Union usc:6698 FoR 0406 (Physical Geography and Environmental Geoscience) climate change Quaternary Conference Abstract 2010 ftunivscoast 2020-05-11T22:26:12Z The Australian continent is the largest source of dust in the Southern Hemisphere. Historical dust emissions records display inter-annual variability in response to the El Niño Southern Oscillation (ENSO) phenomenon and inter-decadal variability which has been linked to the Pacific Decadal Oscillation (PDO). These reflect change in hydrometeorology of the continents two major dust source regions, the Murray-Darling Basin and the Lake Eyre Basin. The historical records do not allow longer term variability of ENSO and the PDO and their influence on Australia to be quantified. Importantly, sub-Milankovitch centennial to multi-millennial scale climate cycles and their impacts are not represented in the historical records. In this paper we present summary results from the analysis of two aeolain dust records spanning 7 ka and 45 ka. These were developed from ombrotrophic mire and lacustrine sediment cores collected from the Australian Alps and southeast Queensland. Both sites are located in the southeast Australian dust transport pathway and provide rare insight to forcings of climate variability and its impacts on eastern Australia through the late Quaternary. Age controls for the cores were established using 14C and 210Pb dating [McGowan et al. 2008, 2010]. The cores were sliced into 2 to 5 mm segments with a sub-sample of each segment combusted at 450°C for 12 hrs to destroy organic material and allow recovery of mineral dust. Geochemical fingerprinting of the < 90 µm fraction of the dust was used to determine provenance and to account for contamination by fluvial and/or colluvial sediments [Marx et al. 2005]. Analysis of the dust records, proxy for hydrometeorology, identified tropical ocean teleconnections, variability of solar irradiance and change in ocean deep water circulation as the principal causes of inter-decadal to centennial scale climate cycles and change. Predictions of future climate must consider these forcings so that in water scarce regions of Australia the effect on the hydroclimate is incorporated into the design of water allocation policy and infrastructure, and the management of environmental systems. Comparison with ice core records from Greenland and Antarctica indicate both synchronicity of global climate variability and the impact of forcings originating from the North Hemisphere. These results highlight the potential for adverse impacts on the climate of Australia by disturbance to North Atlantic Ocean circulation. Conference Object Antarc* Antarctica Greenland ice core North Atlantic University of the Sunshine Coast, Queensland, Australia: COAST Research Database Greenland Pacific Queensland
institution Open Polar
collection University of the Sunshine Coast, Queensland, Australia: COAST Research Database
op_collection_id ftunivscoast
language English
topic FoR 0406 (Physical Geography and Environmental Geoscience)
climate change
Quaternary
spellingShingle FoR 0406 (Physical Geography and Environmental Geoscience)
climate change
Quaternary
McGowan, H A
Marx, S K
Soderholm, J
Denholm, J
Petherick, L
Insight to forcing of late Quaternary climate change from aeolian dust archives in eastern Australia
topic_facet FoR 0406 (Physical Geography and Environmental Geoscience)
climate change
Quaternary
description The Australian continent is the largest source of dust in the Southern Hemisphere. Historical dust emissions records display inter-annual variability in response to the El Niño Southern Oscillation (ENSO) phenomenon and inter-decadal variability which has been linked to the Pacific Decadal Oscillation (PDO). These reflect change in hydrometeorology of the continents two major dust source regions, the Murray-Darling Basin and the Lake Eyre Basin. The historical records do not allow longer term variability of ENSO and the PDO and their influence on Australia to be quantified. Importantly, sub-Milankovitch centennial to multi-millennial scale climate cycles and their impacts are not represented in the historical records. In this paper we present summary results from the analysis of two aeolain dust records spanning 7 ka and 45 ka. These were developed from ombrotrophic mire and lacustrine sediment cores collected from the Australian Alps and southeast Queensland. Both sites are located in the southeast Australian dust transport pathway and provide rare insight to forcings of climate variability and its impacts on eastern Australia through the late Quaternary. Age controls for the cores were established using 14C and 210Pb dating [McGowan et al. 2008, 2010]. The cores were sliced into 2 to 5 mm segments with a sub-sample of each segment combusted at 450°C for 12 hrs to destroy organic material and allow recovery of mineral dust. Geochemical fingerprinting of the < 90 µm fraction of the dust was used to determine provenance and to account for contamination by fluvial and/or colluvial sediments [Marx et al. 2005]. Analysis of the dust records, proxy for hydrometeorology, identified tropical ocean teleconnections, variability of solar irradiance and change in ocean deep water circulation as the principal causes of inter-decadal to centennial scale climate cycles and change. Predictions of future climate must consider these forcings so that in water scarce regions of Australia the effect on the hydroclimate is incorporated into the design of water allocation policy and infrastructure, and the management of environmental systems. Comparison with ice core records from Greenland and Antarctica indicate both synchronicity of global climate variability and the impact of forcings originating from the North Hemisphere. These results highlight the potential for adverse impacts on the climate of Australia by disturbance to North Atlantic Ocean circulation.
format Conference Object
author McGowan, H A
Marx, S K
Soderholm, J
Denholm, J
Petherick, L
author_facet McGowan, H A
Marx, S K
Soderholm, J
Denholm, J
Petherick, L
author_sort McGowan, H A
title Insight to forcing of late Quaternary climate change from aeolian dust archives in eastern Australia
title_short Insight to forcing of late Quaternary climate change from aeolian dust archives in eastern Australia
title_full Insight to forcing of late Quaternary climate change from aeolian dust archives in eastern Australia
title_fullStr Insight to forcing of late Quaternary climate change from aeolian dust archives in eastern Australia
title_full_unstemmed Insight to forcing of late Quaternary climate change from aeolian dust archives in eastern Australia
title_sort insight to forcing of late quaternary climate change from aeolian dust archives in eastern australia
publisher American Geophysical Union
publishDate 2010
url http://www.agu.org/meetings/fm10/
geographic Greenland
Pacific
Queensland
geographic_facet Greenland
Pacific
Queensland
genre Antarc*
Antarctica
Greenland
ice core
North Atlantic
genre_facet Antarc*
Antarctica
Greenland
ice core
North Atlantic
op_relation usc:6698
_version_ 1766263921362075648

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