Strong contrast in mass and energy balance between a coastal mountain glacier and the Greenland ice sheet

We show a strong difference in surface mass and energy balance of a mountain glacier and two sites on the ice sheet at 64°N in West Greenland using stake and automated weather station observations. Net surface mass balance is on average 2.2 m w.e. less negative at the coast compared with the ice she...

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Bibliographic Details
Published in:Journal of glaciology 2019-04, Vol.65 (250), p.263-269
Main Authors: ABERMANN, JAKOB, VAN AS, DIRK, WACKER, STEFAN, LANGLEY, KIRSTY, MACHGUTH, HORST, FAUSTO, ROBERT SCHJØTT
Format: Article
Language:English
Subjects:
Climate change
Cloud cover
Cloudiness
Coasts
Cryosphere
Ecosystems
Elevation
Energy
Energy balance
Glaciation
glacier mass balance
Glacier snow cover
Glaciers
Greenland ice sheet
Heat exchange
Heat transfer
Ice
Ice sheets
Long wave radiation
Mass
Mass balance
Mass balance of glaciers
Mountain glaciers
Radiation
Short wave radiation
Snow cover
Weather stations
Wind speed
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Summary:We show a strong difference in surface mass and energy balance of a mountain glacier and two sites on the ice sheet at 64°N in West Greenland using stake and automated weather station observations. Net surface mass balance is on average 2.2 m w.e. less negative at the coast compared with the ice sheet in the same elevation. We find a larger energy turnover at the ice sheet margin on Qamanarssup Sermia than measured on the coastal mountain glacier Qassigiannguit with both energy input and output being of larger absolute value. More cloudiness and a thicker snow cover at the relatively humid coastal glacier result in smaller gains in net-shortwave radiation and smaller losses in net-longwave radiation and a less negative mass balance. Lower wind speeds at the coastal glacier result in weaker turbulent heat exchange between atmosphere and ice surface. On annual average, 17 W m−2 more energy is available for melt at the ice-sheet margin compared with the coastal glacier in the same elevation.
ISSN:0022-1430
1727-5652
DOI:10.1017/jog.2019.4