The influence of air temperature inversions on snowmelt and glacier mass-balance simulations, Ammassalik island, SE Greenland

In many applications, a realistic description of air temperature inversions is essential for accurate snow and glacier ice melt, and glacier mass-balance simulations. A physically based snow-evolution modeling system (SnowModel) was used to simulate eight years (1998/99 to 2005/06) of snow accumulat...

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Main Authors: Mernild, Sebastian Haugard, Liston, Glen
Language:unknown
Published: 2021
Subjects:
58
ABLATION
ALTITUDE
DISTRIBUTION
GLACIERS
GREENLAND
HEAT EXCHANGERS
MASS BALANCE
PRECIPITATION
SEA LEVEL
SEAS
SIMULATION
SNOW
TEMPERATURE DISTRIBUTION
TEMPERATURE INVERSIONS
Greenland
Ammassalik
glacier
Online Access:http://www.osti.gov/servlets/purl/971305
https://www.osti.gov/biblio/971305
id ftosti:oai:osti.gov:971305
record_format openpolar
spelling ftosti:oai:osti.gov:971305 2023-07-30T03:55:58+02:00 The influence of air temperature inversions on snowmelt and glacier mass-balance simulations, Ammassalik island, SE Greenland Mernild, Sebastian Haugard Liston, Glen 2021-02-12 application/pdf http://www.osti.gov/servlets/purl/971305 https://www.osti.gov/biblio/971305 unknown http://www.osti.gov/servlets/purl/971305 https://www.osti.gov/biblio/971305 58 ABLATION ALTITUDE DISTRIBUTION GLACIERS GREENLAND HEAT EXCHANGERS MASS BALANCE PRECIPITATION SEA LEVEL SEAS SIMULATION SNOW TEMPERATURE DISTRIBUTION TEMPERATURE INVERSIONS 2021 ftosti 2023-07-11T08:48:02Z In many applications, a realistic description of air temperature inversions is essential for accurate snow and glacier ice melt, and glacier mass-balance simulations. A physically based snow-evolution modeling system (SnowModel) was used to simulate eight years (1998/99 to 2005/06) of snow accumulation and snow and glacier ice ablation from numerous small coastal marginal glaciers on the SW-part of Ammassalik Island in SE Greenland. These glaciers are regularly influenced by inversions and sea breezes associated with the adjacent relatively low temperature and frequently ice-choked fjords and ocean. To account for the influence of these inversions on the spatiotemporal variation of air temperature and snow and glacier melt rates, temperature inversion routines were added to MircoMet, the meteorological distribution sub-model used in SnowModel. The inversions were observed and modeled to occur during 84% of the simulation period. Modeled inversions were defined not to occur during days with strong winds and high precipitation rates due to the potential of inversion break-up. Field observations showed inversions to extend from sea level to approximately 300 m a.s.l., and this inversion level was prescribed in the model simulations. Simulations with and without the inversion routines were compared. The inversion model produced air temperature distributions with warmer lower elevation areas and cooler higher elevation areas than without inversion routines due to the use of cold sea-breeze base temperature data from underneath the inversion. This yielded an up to 2 weeks earlier snowmelt in the lower areas and up to 1 to 3 weeks later snowmelt in the higher elevation areas of the simulation domain. Averaged mean annual modeled surface mass-balance for all glaciers (mainly located above the inversion layer) was -720 {+-} 620 mm w.eq. y{sup -1} for inversion simulations, and -880 {+-} 620 mm w.eq. y{sup -1} without the inversion routines, a difference of 160 mm w.eq. y{sup -1}. The annual glacier loss for the two ... Other/Unknown Material Ammassalik glacier Greenland SciTec Connect (Office of Scientific and Technical Information - OSTI, U.S. Department of Energy) Greenland
institution Open Polar
collection SciTec Connect (Office of Scientific and Technical Information - OSTI, U.S. Department of Energy)
op_collection_id ftosti
language unknown
topic 58
ABLATION
ALTITUDE
DISTRIBUTION
GLACIERS
GREENLAND
HEAT EXCHANGERS
MASS BALANCE
PRECIPITATION
SEA LEVEL
SEAS
SIMULATION
SNOW
TEMPERATURE DISTRIBUTION
TEMPERATURE INVERSIONS
spellingShingle 58
ABLATION
ALTITUDE
DISTRIBUTION
GLACIERS
GREENLAND
HEAT EXCHANGERS
MASS BALANCE
PRECIPITATION
SEA LEVEL
SEAS
SIMULATION
SNOW
TEMPERATURE DISTRIBUTION
TEMPERATURE INVERSIONS
Mernild, Sebastian Haugard
Liston, Glen
The influence of air temperature inversions on snowmelt and glacier mass-balance simulations, Ammassalik island, SE Greenland
topic_facet 58
ABLATION
ALTITUDE
DISTRIBUTION
GLACIERS
GREENLAND
HEAT EXCHANGERS
MASS BALANCE
PRECIPITATION
SEA LEVEL
SEAS
SIMULATION
SNOW
TEMPERATURE DISTRIBUTION
TEMPERATURE INVERSIONS
description In many applications, a realistic description of air temperature inversions is essential for accurate snow and glacier ice melt, and glacier mass-balance simulations. A physically based snow-evolution modeling system (SnowModel) was used to simulate eight years (1998/99 to 2005/06) of snow accumulation and snow and glacier ice ablation from numerous small coastal marginal glaciers on the SW-part of Ammassalik Island in SE Greenland. These glaciers are regularly influenced by inversions and sea breezes associated with the adjacent relatively low temperature and frequently ice-choked fjords and ocean. To account for the influence of these inversions on the spatiotemporal variation of air temperature and snow and glacier melt rates, temperature inversion routines were added to MircoMet, the meteorological distribution sub-model used in SnowModel. The inversions were observed and modeled to occur during 84% of the simulation period. Modeled inversions were defined not to occur during days with strong winds and high precipitation rates due to the potential of inversion break-up. Field observations showed inversions to extend from sea level to approximately 300 m a.s.l., and this inversion level was prescribed in the model simulations. Simulations with and without the inversion routines were compared. The inversion model produced air temperature distributions with warmer lower elevation areas and cooler higher elevation areas than without inversion routines due to the use of cold sea-breeze base temperature data from underneath the inversion. This yielded an up to 2 weeks earlier snowmelt in the lower areas and up to 1 to 3 weeks later snowmelt in the higher elevation areas of the simulation domain. Averaged mean annual modeled surface mass-balance for all glaciers (mainly located above the inversion layer) was -720 {+-} 620 mm w.eq. y{sup -1} for inversion simulations, and -880 {+-} 620 mm w.eq. y{sup -1} without the inversion routines, a difference of 160 mm w.eq. y{sup -1}. The annual glacier loss for the two ...
author Mernild, Sebastian Haugard
Liston, Glen
author_facet Mernild, Sebastian Haugard
Liston, Glen
author_sort Mernild, Sebastian Haugard
title The influence of air temperature inversions on snowmelt and glacier mass-balance simulations, Ammassalik island, SE Greenland
title_short The influence of air temperature inversions on snowmelt and glacier mass-balance simulations, Ammassalik island, SE Greenland
title_full The influence of air temperature inversions on snowmelt and glacier mass-balance simulations, Ammassalik island, SE Greenland
title_fullStr The influence of air temperature inversions on snowmelt and glacier mass-balance simulations, Ammassalik island, SE Greenland
title_full_unstemmed The influence of air temperature inversions on snowmelt and glacier mass-balance simulations, Ammassalik island, SE Greenland
title_sort influence of air temperature inversions on snowmelt and glacier mass-balance simulations, ammassalik island, se greenland
publishDate 2021
url http://www.osti.gov/servlets/purl/971305
https://www.osti.gov/biblio/971305
geographic Greenland
geographic_facet Greenland
genre Ammassalik
glacier
Greenland
genre_facet Ammassalik
glacier
Greenland
op_relation http://www.osti.gov/servlets/purl/971305
https://www.osti.gov/biblio/971305
_version_ 1772810400285327360

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