Snowfall and water stable isotope variability in East Antarctica controlled by warm synoptic events

Understanding climate proxy records that preserve physical characteristics of past climate is a prerequisite to reconstruct long‐term climatic conditions. Water stable isotope ratios (δ 18 O) constitute a widely used proxy in ice cores to reconstruct temperature and climate. However, the original cl...

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Bibliographic Details
Published in:Journal of Geophysical Research: Atmospheres
Main Authors: Servettaz, APM, Orsi, AJ, Curran, MAJ, Moy, AD, Landais, A, Agosta, C, Winton, VHL, Touzeau, A, McConnell, JR, Werner, M, Baroni, M
Format: Article in Journal/Newspaper
Language:English
Published: Wiley-Blackwell Publishing Inc. 2020
Subjects:
Online Access:https://doi.org/10.1029/2020JD032863
http://ecite.utas.edu.au/140706
Description
Summary:Understanding climate proxy records that preserve physical characteristics of past climate is a prerequisite to reconstruct long‐term climatic conditions. Water stable isotope ratios (δ 18 O) constitute a widely used proxy in ice cores to reconstruct temperature and climate. However, the original climate signal is altered between the formation of precipitation and the ice, especially in low‐accumulation areas such as the East Antarctic Plateau. Atmospheric conditions under which the isotopic signal is acquired at Aurora Basin North (ABN), East Antarctica, are characterized with the regional atmospheric model Modle Atmosphrique Rgional (MAR). The model shows that 50% of the snow is accumulated in less than 24daysyear −1 . Snowfall occurs throughout the year and intensifies during winter, with 64% of total accumulation between April and September, leading to a cold bias of −0.86C in temperatures above inversion compared to the annual mean of −29.7C. Large snowfall events are associated with high‐pressure systems forcing warm oceanic air masses toward the Antarctic interior, which causes a warm bias of +2.83C. The temperature‐δ 18 O relationship, assessed with the global atmospheric model ECHAM5‐wiso, is primarily constrained by the winter variability, but the observed slope is valid year‐round. Three snow δ 18 O records covering 20042014 indicate that the anomalies recorded in the ice core are attributable to the occurrence of warm winter storms bringing precipitation to ABN and support the interpretation of δ 18 O in this region as a marker of temperature changes related to large‐scale atmospheric conditions, particularly blocking events and variations in the Southern Annular Mode.