Glacier‐based climate reconstructions for the last glacial–interglacial transition: Arthur's Pass, New Zealand (43°S)

ABSTRACT Geological records of mountain glacier fluctuations provide useful evidence for tracing the magnitude and rate of past temperature change. In this study, we present air temperature reconstructions for the last glacial termination in New Zealand derived using snowline reconstructions and num...

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Published in:Journal of quaternary science 2017-08, Vol.32 (6), p.877-887
Main Authors: Eaves, Shaun R., Anderson, Brian M., Mackintosh, Andrew N.
Format: Article
Language:English
Subjects:
Age
Air temperature
Beryllium 10
Catchments
Climate
Coastal plains
Glacier fluctuations
glacier modelling
Glacier retreat
Glaciers
Heinrich Stadial 1
Ice
last glacial termination
Mathematical models
Moraines
Mountain glaciers
palaeoclimate
River catchments
Rivers
Snowline
Southern Hemisphere
Temperature changes
Temperature effects
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description ABSTRACT Geological records of mountain glacier fluctuations provide useful evidence for tracing the magnitude and rate of past temperature change. In this study, we present air temperature reconstructions for the last glacial termination in New Zealand derived using snowline reconstructions and numerical glacier modelling. We target the Arthur's Pass moraines in the Otira River catchment, which have previously been dated to the Lateglacial using cosmogenic 10Be. Recalculation of these exposure ages using a locally calibrated 10Be production rate indicates that these moraines formed ca. 16–14 ka. Our glacier modelling experiments and snowline reconstructions exhibit good agreement and show that the Arthur's Pass moraines formed in a climate that was 2.2–3.5 °C colder than present. Combining our results with other, proximal glacier records shows that ice in this catchment retreated ca. 50 km from the coastal plain to the main divide during the interval 17–15 ka, in response to a temperature increase of at least ca. 3 °C. Over half of this retreat occurred after the glacier had withdrawn from an overdeepened basin. Thus, we conclude that temperature increase was the primary driver of widespread and rapid glacier retreat in New Zealand at the onset of the last glacial termination.
doi_str_mv 10.1002/jqs.2904
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subjects Age
Air temperature
Beryllium 10
Catchments
Climate
Coastal plains
Glacier fluctuations
glacier modelling
Glacier retreat
Glaciers
Heinrich Stadial 1
Ice
last glacial termination
Mathematical models
Moraines
Mountain glaciers
palaeoclimate
River catchments
Rivers
Snowline
Southern Hemisphere
Temperature changes
Temperature effects
title Glacier‐based climate reconstructions for the last glacial–interglacial transition: Arthur's Pass, New Zealand (43°S)
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