Surface and snowdrift sublimation at Princess Elisabeth station, East Antarctica

W Thiery,R Bintanja,P Kuipers Munneke,N P M Van Lipzig,I V Gorodetskaya,C H Reijmer,M R Van Den Broeke

doi:10.5194/tc-6-841-2012

W Thiery, R Bintanja + Show 5 more

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https://doi.org/10.5194/tc-6-841-2012

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Abstract

Abstract. In the near-coastal regions of Antarctica, a significant fraction of the snow precipitating onto the surface is removed again through sublimation – either directly from the surface or from drifting snow particles. Meteorological observations from an Automatic Weather Station (AWS) near the Belgian research station Princess Elisabeth in Dronning Maud Land, East-Antarctica, are used to study surface and snowdrift sublimation and to assess their impacts on both the surface mass balance and the surface energy balance during 2009 and 2010. Comparison to three other AWSs in Dronning Maud Land with 11 to 13 yr of observations shows that sublimation has a significant influence on the surface mass balance at katabatic locations by removing 10–23% of their total precipitation, but at the same time reveals anomalously low surface and snowdrift sublimation rates at Princess Elisabeth (17 mm w.e. yr−1 compared to 42 mm w.e. yr−1 at Svea Cross and 52 mm w.e. yr−1 at Wasa/Aboa). This anomaly is attributed to local topography, which shields the station from strong katabatic influence, and, therefore, on the one hand allows for a strong surface inversion to persist throughout most of the year and on the other hand causes a lower probability of occurrence of intermediately strong winds. This wind speed class turns out to contribute most to the total snowdrift sublimation mass flux, given its ability to lift a high number of particles while still allowing for considerable undersaturation.

Highlights

The surface mass balance (SMB) includes the input and/or removal of mass at the surface and constitutes an essential part of the total mass balance of glaciers and ice sheets
The process is characterised by a strong spatial variability: in the extremely cold interior of the Antarctic ice sheet, SUs is virtually absent (Dery and Yau, 2002), whereas blue ice areas are associated with high sublimation rates (e.g. at Seal rock in the Sør Rondane mountains, Takahashi et al (1992) recorded SUs rates from −200 to −280 mm w.e. yr−1 over a blue ice area)
Remarkable differences were found between Automatic Weather Station (AWS) 16 and two other katabatic stations in Dronning Maud Land

Summary

Introduction

The surface mass balance (SMB) includes the input and/or removal of mass at the surface and constitutes an essential part of the total mass balance of glaciers and ice sheets. With the different terms of the SMB being total (solid and liquid) precipitation (PR), liquid water runoff (RU), erosion (deposition) due to divergence (convergence) of horizontal snowdrift transport (ERds), surface sublimation (deposition) (SUs) and sublimation of drifting snow particles within a column extending from the surface to the top of the drifting snow layer (SUds) (Van den Broeke et al, 2004a). Note that in this definition, each term is defined negative when it removes mass from the surface. The process is characterised by a strong spatial variability: in the extremely cold interior of the Antarctic ice sheet, SUs is virtually absent (Dery and Yau, 2002), whereas blue ice areas are associated with high sublimation rates (e.g. at Seal rock in the Sør Rondane mountains, Takahashi et al (1992) recorded SUs rates from −200 to −280 mm w.e. yr−1 over a blue ice area)

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