TY - JOUR
T1 - Greenland Surface Mass Balance as Simulated by the Community Earth System Model. Part II: Twenty-First-Century Changes
AU - Vizcaino, M.
AU - Lipscomb, W.H.
AU - Sacks, W.J.
AU - van den Broeke, M.R.
PY - 2014
Y1 - 2014
N2 - This study presents the first twenty-first-century projections of surface mass balance (SMB) changes for the
Greenland Ice Sheet (GIS) with the Community Earth System Model (CESM), which includes a new ice sheet
component. For glaciated surfaces, CESM includes a sophisticated calculation of energy fluxes, surface albedo,
and snowpack hydrology (melt, percolation, refreezing, etc.). To efficiently resolve the high SMB
gradients at the ice sheet margins and provide surface forcing at the scale needed by ice sheet models, the
SMB is calculated at multiple elevations and interpolated to a finer 5-km ice sheet grid. During a twenty-firstcentury
simulation driven by representative concentration pathway 8.5 (RCP8.5) forcing, the SMB decreases
from 372 6 100 Gt yr21 in 1980–99 to 278 6 143 Gt yr21 in 2080–99. The 2080–99 near-surface temperatures
over the GIS increase by 4.7K (annual mean) with respect to 1980–99, only 1.3 times the global increase
(13.7 K). Snowfall increases by 18%, while surface melt doubles. The ablation area increases from 9% of the
GIS in 1980–99 to 28% in 2080–99. Over the ablation areas, summer downward longwave radiation and
turbulent fluxes increase, while incoming shortwave radiation decreases owing to increased cloud cover. The
reduction in GIS-averaged July albedo from 0.78 in 1980–99 to 0.75 in 2080–99 increases the absorbed solar
radiation in this month by 12%. Summer warming is strongest in the north and east of Greenland owing to
reduced sea ice cover. In the ablation area, summer temperature increases are smaller due to frequent periods
of surface melt.
AB - This study presents the first twenty-first-century projections of surface mass balance (SMB) changes for the
Greenland Ice Sheet (GIS) with the Community Earth System Model (CESM), which includes a new ice sheet
component. For glaciated surfaces, CESM includes a sophisticated calculation of energy fluxes, surface albedo,
and snowpack hydrology (melt, percolation, refreezing, etc.). To efficiently resolve the high SMB
gradients at the ice sheet margins and provide surface forcing at the scale needed by ice sheet models, the
SMB is calculated at multiple elevations and interpolated to a finer 5-km ice sheet grid. During a twenty-firstcentury
simulation driven by representative concentration pathway 8.5 (RCP8.5) forcing, the SMB decreases
from 372 6 100 Gt yr21 in 1980–99 to 278 6 143 Gt yr21 in 2080–99. The 2080–99 near-surface temperatures
over the GIS increase by 4.7K (annual mean) with respect to 1980–99, only 1.3 times the global increase
(13.7 K). Snowfall increases by 18%, while surface melt doubles. The ablation area increases from 9% of the
GIS in 1980–99 to 28% in 2080–99. Over the ablation areas, summer downward longwave radiation and
turbulent fluxes increase, while incoming shortwave radiation decreases owing to increased cloud cover. The
reduction in GIS-averaged July albedo from 0.78 in 1980–99 to 0.75 in 2080–99 increases the absorbed solar
radiation in this month by 12%. Summer warming is strongest in the north and east of Greenland owing to
reduced sea ice cover. In the ablation area, summer temperature increases are smaller due to frequent periods
of surface melt.
U2 - 10.1175/JCLI-D-12-00588.1
DO - 10.1175/JCLI-D-12-00588.1
M3 - Article
SN - 0894-8755
VL - 27
SP - 215
EP - 226
JO - Journal of Climate
JF - Journal of Climate
ER -