Abstract
Accurate quantification of surface snow accumulation over
Antarctica is a key constraint for estimates of the Antarctic
mass balance, as well as climatic interpretations of ice-core
records1,2. Over Antarctica, near-surface winds accelerate
down relatively steep surface slopes, eroding and sublimating
the snow. This wind scour results in numerous localized
regions ( 200 km2) with reduced surface accumulation3–7.
Estimates of Antarctic surface mass balance rely on sparse
point measurements or coarse atmospheric models that do
not capture these local processes, and overestimate the net
mass input in wind-scour zones3. Here we combine airborne
radar observations of unconformable stratigraphic layers with
lidar-derived surface roughness measurements to identify
extensive wind-scour zones over Dome A, in the interior of
East Antarctica. The scour zones are persistent because they
are controlled by bedrock topography. On the basis of our
DomeAobservations,we develop an empirical model to predict
wind-scour zones across the Antarctic continent and find that
these zones are predominantly located in East Antarctica. We
estimate that 2.7–6.6% of the surface area of Antarctica
has persistent negative net accumulation due to wind scour,
which suggests that, across the continent, the snow mass input
is overestimated by 11–36:5 Gt yr1 in present surface-massbalance
calculations.
Original language | English |
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Pages (from-to) | 367-371 |
Number of pages | 5 |
Journal | Nature Geoscience |
Volume | 6 |
DOIs | |
Publication status | Published - 2013 |