Changing surface–atmosphere energy exchange and refreezing capacity of the lower accumulation area, West Greenland
Permanent link
https://hdl.handle.net/10037/8666Date
2015-11-18Type
Journal articleTidsskriftartikkel
Peer reviewed
Author
Charalampidis, C.; Van As, D.; Box, J.E.; van den Broeke, M.R.; Colgan, W.T.; Doyle, S.H.; Hubbard, Alun Lloyd; MacFerrin, M.; Machguth, H.; Smeets, C.J.P.P.Abstract
We present 5 years (2009–2013) of automatic
weather station measurements from the lower accumulation
area (1840 m a.s.l. – above sea level) of the Greenland ice
sheet in the Kangerlussuaq region. Here, the summers of
2010 and 2012 were both exceptionally warm, but only 2012
resulted in a strongly negative surface mass budget (SMB)
and surface meltwater run-off. The observed run-off was due
to a large ice fraction in the upper 10 m of firn that prevented
meltwater from percolating to available pore volume below.
Analysis reveals an anomalously low 2012 summer-averaged
albedo of 0.71 (typically ∼ 0.78), as meltwater was present
at the ice sheet surface. Consequently, during the 2012 melt
season, the ice sheet surface absorbed 28 % (213 MJ m−2
)
more solar radiation than the average of all other years.
A surface energy balance model is used to evaluate the seasonal
and interannual variability of all surface energy fluxes.
The model reproduces the observed melt rates as well as the
SMB for each season. A sensitivity analysis reveals that 71 %
of the additional solar radiation in 2012 was used for melt,
corresponding to 36 % (0.64 m) of the 2012 surface lowering.
The remaining 64 % (1.14 m) of surface lowering resulted
from high atmospheric temperatures, up to a +2.6 ◦C
daily average, indicating that 2012 would have been a negative
SMB year at this site even without the melt–albedo feedback.
Longer time series of SMB, regional temperature, and remotely
sensed albedo (MODIS) show that 2012 was the first
strongly negative SMB year, with the lowest albedo, at this
elevation on record. The warm conditions of recent years
have resulted in enhanced melt and reduction of the refreezing
capacity in the lower accumulation area. If high temperatures
continue, the current lower accumulation area will turn
into a region with superimposed ice in coming years.