Simulating airborne 'snow walls' of Antarctica using CRYOWRF v1.0

When a well-developed, high velocity katabatic flow draining down the ice sheet of Antarctica reaches the coast, it experiences an abrupt and rapid transition due to change in slope resulting in formation of a hydraulic jump. A remarkable manifestation of the hydraulic jump, given the "right&qu...

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Main Authors: Sharma, Varun, Gerber, Franziska, Lehning, Michael
Format: Text
Language:unknown
Published: 2022
Subjects:
Antarc*
Antarctica
Ice Sheet
Online Access:https://infoscience.epfl.ch/record/292645/files/EGU21-13429-print.pdf
http://infoscience.epfl.ch/record/292645
id ftinfoscience:oai:infoscience.epfl.ch:292645
record_format openpolar
spelling ftinfoscience:oai:infoscience.epfl.ch:292645 2023-05-15T13:43:17+02:00 Simulating airborne 'snow walls' of Antarctica using CRYOWRF v1.0 Sharma, Varun Gerber, Franziska Lehning, Michael 2022-03-11T08:27:59Z https://infoscience.epfl.ch/record/292645/files/EGU21-13429-print.pdf http://infoscience.epfl.ch/record/292645 unknown https://infoscience.epfl.ch/record/292645/files/EGU21-13429-print.pdf http://infoscience.epfl.ch/record/292645 http://infoscience.epfl.ch/record/292645 Text 2022 ftinfoscience 2023-02-13T23:09:09Z When a well-developed, high velocity katabatic flow draining down the ice sheet of Antarctica reaches the coast, it experiences an abrupt and rapid transition due to change in slope resulting in formation of a hydraulic jump. A remarkable manifestation of the hydraulic jump, given the "right" surface conditions, is the large-scale entrainment and convergence of blowing snow particles within the hydraulic jump. This can result in formation of 100-1000 m high, highly localized "walls" of snow in the air in an otherwise cloud-free sky.Recent work by Vignon et al. (2020) has described in detail, the mechanisms resulting in the formation of hydraulic jumps and excitation of gravity waves during a particularly notable event at the Dumont d"Urville (DDU) station in August 2017. They used a combination of satellite images, mesoscale simulations with WRF and station measurements (including Micro Rain Radars) in their study, notably relying on the snow wall for diagnosing and quantifying the hydraulic jump in satellite images. On the other hand, relatively less importance was given towards the surface snow processes including the transport of snow particles in the wall.In this presentation, we present results from simulations done using the recently developed CRYOWRF v1.0 to recreate the August 2017 episode at DDU and explicitly simulate the formation and the dynamics of the snow wall itself. CRYOWRF enhances the standard WRF model with the state-of-the-art surface snow modelling scheme SNOWPACK as well as a completely new blowing snow scheme. SNOWPACK essentially acts as a land surface model for the WRF atmospheric model, thus making a quantum leap over the existing snow cover models in WRF. Since SNOWPACK is a grain-scale snow model, it allows for the proper formulation of boundary conditions for simulating blowing snow dynamics.Results show the formation of the snow wall due to large scale entrainment over a wide area of the ice sheet, the mass balance of the snow wall within the hydraulic jump and finally, the ... Text Antarc* Antarctica Ice Sheet EPFL Infoscience (Ecole Polytechnique Fédérale Lausanne)
institution Open Polar
collection EPFL Infoscience (Ecole Polytechnique Fédérale Lausanne)
op_collection_id ftinfoscience
language unknown
description When a well-developed, high velocity katabatic flow draining down the ice sheet of Antarctica reaches the coast, it experiences an abrupt and rapid transition due to change in slope resulting in formation of a hydraulic jump. A remarkable manifestation of the hydraulic jump, given the "right" surface conditions, is the large-scale entrainment and convergence of blowing snow particles within the hydraulic jump. This can result in formation of 100-1000 m high, highly localized "walls" of snow in the air in an otherwise cloud-free sky.Recent work by Vignon et al. (2020) has described in detail, the mechanisms resulting in the formation of hydraulic jumps and excitation of gravity waves during a particularly notable event at the Dumont d"Urville (DDU) station in August 2017. They used a combination of satellite images, mesoscale simulations with WRF and station measurements (including Micro Rain Radars) in their study, notably relying on the snow wall for diagnosing and quantifying the hydraulic jump in satellite images. On the other hand, relatively less importance was given towards the surface snow processes including the transport of snow particles in the wall.In this presentation, we present results from simulations done using the recently developed CRYOWRF v1.0 to recreate the August 2017 episode at DDU and explicitly simulate the formation and the dynamics of the snow wall itself. CRYOWRF enhances the standard WRF model with the state-of-the-art surface snow modelling scheme SNOWPACK as well as a completely new blowing snow scheme. SNOWPACK essentially acts as a land surface model for the WRF atmospheric model, thus making a quantum leap over the existing snow cover models in WRF. Since SNOWPACK is a grain-scale snow model, it allows for the proper formulation of boundary conditions for simulating blowing snow dynamics.Results show the formation of the snow wall due to large scale entrainment over a wide area of the ice sheet, the mass balance of the snow wall within the hydraulic jump and finally, the ...
format Text
author Sharma, Varun
Gerber, Franziska
Lehning, Michael
spellingShingle Sharma, Varun
Gerber, Franziska
Lehning, Michael
Simulating airborne 'snow walls' of Antarctica using CRYOWRF v1.0
author_facet Sharma, Varun
Gerber, Franziska
Lehning, Michael
author_sort Sharma, Varun
title Simulating airborne 'snow walls' of Antarctica using CRYOWRF v1.0
title_short Simulating airborne 'snow walls' of Antarctica using CRYOWRF v1.0
title_full Simulating airborne 'snow walls' of Antarctica using CRYOWRF v1.0
title_fullStr Simulating airborne 'snow walls' of Antarctica using CRYOWRF v1.0
title_full_unstemmed Simulating airborne 'snow walls' of Antarctica using CRYOWRF v1.0
title_sort simulating airborne 'snow walls' of antarctica using cryowrf v1.0
publishDate 2022
url https://infoscience.epfl.ch/record/292645/files/EGU21-13429-print.pdf
http://infoscience.epfl.ch/record/292645
genre Antarc*
Antarctica
Ice Sheet
genre_facet Antarc*
Antarctica
Ice Sheet
op_source http://infoscience.epfl.ch/record/292645
op_relation https://infoscience.epfl.ch/record/292645/files/EGU21-13429-print.pdf
http://infoscience.epfl.ch/record/292645
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