Snow distribution and melt modeling for Mittivakkat Glacier, Ammassalik Island, southeast Greenland
SH Mernild, GE Liston, B Hasholt… - Journal of …, 2006 - journals.ametsoc.org
SH Mernild, GE Liston, B Hasholt, NT Knudsen
Journal of Hydrometeorology, 2006•journals.ametsoc.orgA physically based snow-evolution modeling system (SnowModel) that includes four
submodels—the Micrometeorological Model (MicroMet), EnBal, SnowPack, and SnowTran-
3D—was used to simulate five full-year evolutions of snow accumulation, distribution,
sublimation, and surface melt on the Mittivakkat Glacier, in southeast Greenland. Model
modifications were implemented and used 1) to adjust underestimated observed
meteorological station solid precipitation until the model matched the observed Mittivakkat …
submodels—the Micrometeorological Model (MicroMet), EnBal, SnowPack, and SnowTran-
3D—was used to simulate five full-year evolutions of snow accumulation, distribution,
sublimation, and surface melt on the Mittivakkat Glacier, in southeast Greenland. Model
modifications were implemented and used 1) to adjust underestimated observed
meteorological station solid precipitation until the model matched the observed Mittivakkat …
Abstract
A physically based snow-evolution modeling system (SnowModel) that includes four submodels—the Micrometeorological Model (MicroMet), EnBal, SnowPack, and SnowTran-3D—was used to simulate five full-year evolutions of snow accumulation, distribution, sublimation, and surface melt on the Mittivakkat Glacier, in southeast Greenland. Model modifications were implemented and used 1) to adjust underestimated observed meteorological station solid precipitation until the model matched the observed Mittivakkat Glacier winter mass balance, and 2) to simulate glacier-ice melt after the winter snow accumulation had ablated. Meteorological observations from two meteorological stations were used as model inputs, and glaciological mass balance observations were used for model calibration and testing of solid precipitation observations. The modeled end-of-winter snow-water equivalent (w.eq.) accumulation increased with elevation from 200 to 700 m above sea level (ASL) in response to both elevation and topographic influences, and the simulated end-of-summer location of the glacier equilibrium line altitude was confirmed by glaciological observations and digital images. The modeled test-period-averaged annual mass balance was 150 mm w.eq. yr −1 , or ∼15%, less than the observed. Approximately 12% of the precipitation was returned to the atmosphere by sublimation. Glacier-averaged mean annual modeled surface melt ranged from 1272 to 2221 mm w.eq. yr −1 , of which snowmelt contributed from 610 to 1040 mm w.eq. yr −1 . The surface-melt period started between mid-May and the beginning of June, and lasted until mid-September; there were as many as 120 melt days at the glacier terminus. The model simulated a Mittivakkat Glacier recession averaging −616 mm w.eq. yr −1 , almost equal to the observed −600 mm w.eq. yr −1 .
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