Comparison of observations and modelling of surface mass balance variations in East Antarctica
Abstract
Mass balance changes of the Antarctic ice sheet are of
significant interest due to its sensitivity to climatic changes
and the contribution to changes in global sea level that is
makes. In recent years, the Antarctic ice sheet has experienced
increased temperatures inducing surface melting, accelerated ice
flow and ice discharge but also an increase in accumulation.
Geodetic observations suggest variable behaviour across the ice
sheet, with an increase in mass over a vast area of East
Antarctica and substantial thinning in West Antarctica.
Despite considerable improvement on surface mass balance
estimates using a variety of techniques, disparity remains mainly
due to uncertainties of each method and the unknown contribution
of glacial isostatic adjustment, the response of the lithosphere
to prolonged surface loads. Estimates of bedrock uplift rates are
limited and existing models are poorly constrained due to the
lack of observations as a result of the extensive permanent ice
coverage in Antarctica.
This study investigates the possibility of combining and
comparing altimetry and gravity observations by employing a
regional climate model to simulate near surface climate and firn
compaction, to separate the contributing ice sheet mass balance
components of surface mass, firn compaction, ice dynamics and
glacial isostatic adjustment within the observed signals. The
region of interest covers an area including Enderby, Kemp and
Mac.Robertson Land, in East Antarctica, an area where an increase
in ice mass and ice height has been recorded over the past
decade. Despite the general agreement that the positive signal is
primarily related to increased snowfall, large uncertainties
remain in bedrock uplift rates in this region due to the lack of
observations.
Estimates of ice dynamic rates are obtained by removing modelled
surface elevation variations, due to surface mass and firn
compaction, from altimetry observations, which are subsequently
employed in models of mass variations to compare with gravimetric
observations.
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