Inter-hemispheric linkages in climate change: Paleo-perspectives for future climate change

The Pole-Equator-Pole (PEP) projects of the PANASH (Paleoclimates of the Northern and Southern Hemisphere) programme have significantly advanced our understanding of past climate change on a global basis and helped to integrate paleo-science across regions and research disciplines. PANASH science al...

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Published in:Climate of the Past
Main Authors: Shulmeister, J., Rodbell, D. T., Gagan, M., Seltzer, G. O.
Other Authors: Julie Brigham-Grette, Thorsten Kiefer, Pinxian Wang, Heinz Wanner
Format: Article in Journal/Newspaper
Language:English
Published: European Geosciences Union 2006
Subjects:
last glacial maximum
nino-southern-oscillation
cosmogenic nuclide chronology
el-nino/southern-oscillation
equilibrium-line altitudes
franz-josef-glacier
new-zealand
late pleistocene
younger dryas
tropical andes
050205 Environmental Management
Antarctic
The Antarctic
Pacific
New Zealand
Antarc*
Antarctica
Online Access:https://espace.library.uq.edu.au/view/UQ:190871/UQ190871_OA.pdf
https://espace.library.uq.edu.au/view/UQ:190871
id ftunivqespace:oai:espace.library.uq.edu.au:UQ:190871
record_format openpolar
spelling ftunivqespace:oai:espace.library.uq.edu.au:UQ:190871 2023-05-15T13:49:28+02:00 Inter-hemispheric linkages in climate change: Paleo-perspectives for future climate change Shulmeister, J. Rodbell, D. T. Gagan, M. Seltzer, G. O. Julie Brigham-Grette Thorsten Kiefer Pinxian Wang Heinz Wanner 2006-01-01 https://espace.library.uq.edu.au/view/UQ:190871/UQ190871_OA.pdf https://espace.library.uq.edu.au/view/UQ:190871 eng eng European Geosciences Union doi:10.5194/cp-2-167-2006 issn:1814-9324 orcid:0000-0001-5863-9462 orcid:0000-0002-8279-323X last glacial maximum nino-southern-oscillation cosmogenic nuclide chronology el-nino/southern-oscillation equilibrium-line altitudes franz-josef-glacier new-zealand late pleistocene younger dryas tropical andes 050205 Environmental Management Journal Article 2006 ftunivqespace https://doi.org/10.5194/cp-2-167-2006 2020-12-14T23:28:25Z The Pole-Equator-Pole (PEP) projects of the PANASH (Paleoclimates of the Northern and Southern Hemisphere) programme have significantly advanced our understanding of past climate change on a global basis and helped to integrate paleo-science across regions and research disciplines. PANASH science allows us to constrain predictions for future climate change and to contribute to the management of consequent environmental changes. We identify three broad areas where PEP science makes key contributions. 1. The pattern of global changes. Knowing the exact timing of glacial advances (synchronous or otherwise) during the last glaciation is critical to understanding interhemispheric links in climate. Work in PEPI demonstrated that the tropical Andes in South America were deglaciated earlier than the Northern Hemisphere (NH) and that an extended warming began there ca. 21 000 cal years BP. The general pattern is consistent with Antarctica and has now been replicated from studies in Southern Hemisphere (SH) regions of the PEPII transect. That significant deglaciation of SH alpine systems and Antarctica led deglaciation of NH ice sheets may reflect either i) faster response times in alpine systems and Antarctica, ii) regional moisture patterns that influenced glacier mass balance, or iii) a SH temperature forcing that led changes in the NH. This highlights the limitations of current understanding and the need for further fundamental paleoclimate research. 2. Changes in modes of operation of oscillatory climate systems. Work across all the PEP transects has led to the recognition that the El Nino Southern Oscillation (ENSO) phenomenon has changed markedly through time. It now appears that ENSO operated during the last glacial termination and during the early Holocene, but that precipitation teleconnections even within the Pacific Basin were turned down, or off. In the modern ENSO phenomenon both inter-annual and seven year periodicities are present, with the inter-annual signal dominant. Paleo-data demonstrate that the relative importance of the two periodicities changes through time, with longer periodicities dominant in the early Holocene. 3. The recognition of climate modulation of oscillatory systems by climate events. We examine the relationship of ENSO to a SH climate event, the Antarctic cold reversal (ACR), in the New Zealand region. We demonstrate that the onset of the ACR was associated with the apparent switching on of an ENSO signal in New Zealand. We infer that this related to enhanced zonal SW winds with the amplification of the pressure fields allowing an existing but weak ENSO signal to manifest itself. Teleconnections of this nature would be difficult to predict for future abrupt change as boundary conditions cannot readily be specified. Paleo-data are critical to predicting the teleconnections of future changes. Article in Journal/Newspaper Antarc* Antarctic Antarctica The University of Queensland: UQ eSpace Antarctic The Antarctic Pacific New Zealand Climate of the Past 2 2 167 185
institution Open Polar
collection The University of Queensland: UQ eSpace
op_collection_id ftunivqespace
language English
topic last glacial maximum
nino-southern-oscillation
cosmogenic nuclide chronology
el-nino/southern-oscillation
equilibrium-line altitudes
franz-josef-glacier
new-zealand
late pleistocene
younger dryas
tropical andes
050205 Environmental Management
spellingShingle last glacial maximum
nino-southern-oscillation
cosmogenic nuclide chronology
el-nino/southern-oscillation
equilibrium-line altitudes
franz-josef-glacier
new-zealand
late pleistocene
younger dryas
tropical andes
050205 Environmental Management
Shulmeister, J.
Rodbell, D. T.
Gagan, M.
Seltzer, G. O.
Inter-hemispheric linkages in climate change: Paleo-perspectives for future climate change
topic_facet last glacial maximum
nino-southern-oscillation
cosmogenic nuclide chronology
el-nino/southern-oscillation
equilibrium-line altitudes
franz-josef-glacier
new-zealand
late pleistocene
younger dryas
tropical andes
050205 Environmental Management
description The Pole-Equator-Pole (PEP) projects of the PANASH (Paleoclimates of the Northern and Southern Hemisphere) programme have significantly advanced our understanding of past climate change on a global basis and helped to integrate paleo-science across regions and research disciplines. PANASH science allows us to constrain predictions for future climate change and to contribute to the management of consequent environmental changes. We identify three broad areas where PEP science makes key contributions. 1. The pattern of global changes. Knowing the exact timing of glacial advances (synchronous or otherwise) during the last glaciation is critical to understanding interhemispheric links in climate. Work in PEPI demonstrated that the tropical Andes in South America were deglaciated earlier than the Northern Hemisphere (NH) and that an extended warming began there ca. 21 000 cal years BP. The general pattern is consistent with Antarctica and has now been replicated from studies in Southern Hemisphere (SH) regions of the PEPII transect. That significant deglaciation of SH alpine systems and Antarctica led deglaciation of NH ice sheets may reflect either i) faster response times in alpine systems and Antarctica, ii) regional moisture patterns that influenced glacier mass balance, or iii) a SH temperature forcing that led changes in the NH. This highlights the limitations of current understanding and the need for further fundamental paleoclimate research. 2. Changes in modes of operation of oscillatory climate systems. Work across all the PEP transects has led to the recognition that the El Nino Southern Oscillation (ENSO) phenomenon has changed markedly through time. It now appears that ENSO operated during the last glacial termination and during the early Holocene, but that precipitation teleconnections even within the Pacific Basin were turned down, or off. In the modern ENSO phenomenon both inter-annual and seven year periodicities are present, with the inter-annual signal dominant. Paleo-data demonstrate that the relative importance of the two periodicities changes through time, with longer periodicities dominant in the early Holocene. 3. The recognition of climate modulation of oscillatory systems by climate events. We examine the relationship of ENSO to a SH climate event, the Antarctic cold reversal (ACR), in the New Zealand region. We demonstrate that the onset of the ACR was associated with the apparent switching on of an ENSO signal in New Zealand. We infer that this related to enhanced zonal SW winds with the amplification of the pressure fields allowing an existing but weak ENSO signal to manifest itself. Teleconnections of this nature would be difficult to predict for future abrupt change as boundary conditions cannot readily be specified. Paleo-data are critical to predicting the teleconnections of future changes.
author2 Julie Brigham-Grette
Thorsten Kiefer
Pinxian Wang
Heinz Wanner
format Article in Journal/Newspaper
author Shulmeister, J.
Rodbell, D. T.
Gagan, M.
Seltzer, G. O.
author_facet Shulmeister, J.
Rodbell, D. T.
Gagan, M.
Seltzer, G. O.
author_sort Shulmeister, J.
title Inter-hemispheric linkages in climate change: Paleo-perspectives for future climate change
title_short Inter-hemispheric linkages in climate change: Paleo-perspectives for future climate change
title_full Inter-hemispheric linkages in climate change: Paleo-perspectives for future climate change
title_fullStr Inter-hemispheric linkages in climate change: Paleo-perspectives for future climate change
title_full_unstemmed Inter-hemispheric linkages in climate change: Paleo-perspectives for future climate change
title_sort inter-hemispheric linkages in climate change: paleo-perspectives for future climate change
publisher European Geosciences Union
publishDate 2006
url https://espace.library.uq.edu.au/view/UQ:190871/UQ190871_OA.pdf
https://espace.library.uq.edu.au/view/UQ:190871
geographic Antarctic
The Antarctic
Pacific
New Zealand
geographic_facet Antarctic
The Antarctic
Pacific
New Zealand
genre Antarc*
Antarctic
Antarctica
genre_facet Antarc*
Antarctic
Antarctica
op_relation doi:10.5194/cp-2-167-2006
issn:1814-9324
orcid:0000-0001-5863-9462
orcid:0000-0002-8279-323X
op_doi https://doi.org/10.5194/cp-2-167-2006
container_title Climate of the Past
container_volume 2
container_issue 2
container_start_page 167
op_container_end_page 185
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