Testing and application of a model for snow redistribution (Snow_Blow) in the Ellsworth Mountains, Antarctica

Stephanie C. Mills, Anne M. Le Brocq, Kate Winter, Michael Smith, John Hillier, Ekaterina Ardakova, Clare Boston, David Sugden, John Woodward

Research output: Contribution to journalArticlepeer-review

67 Downloads (Pure)


Wind-driven snow redistribution can increase the spatial heterogeneity of snow accumulation on ice caps and ice sheets, and may prove crucial for the initiation and survival of glaciers in areas of marginal glaciation. We present a snowdrift model (Snow_Blow), which extends and improves the model of Purves et al. (1999). The model calculates spatial variations in relative snow accumulation that result from variations in topography, using a digital elevation model (DEM) and wind direction as inputs. Improvements include snow redistribution using a flux routing algorithm, DEM resolution independence and the addition of a slope curvature component. This paper tests Snow_Blow in Antarctica (a modern environment) and reveals its potential for application in palaeo-environmental settings, where input meteorological data are unavailable and difficult to estimate. Specifically, Snow_Blow is applied to the Ellsworth Mountains in West Antarctica where ablation is considered to be predominantly related to wind erosion processes. We find that Snow_Blow is able to replicate well the existing distribution of accumulating snow and snow erosion as recorded in and around Blue Ice Areas. Lastly, a variety of model parameters are tested, including depositional distance and erosion vs wind speed, to provide the most likely input parameters for palaeo-environmental reconstructions.
Original languageEnglish
Pages (from-to)957-970
Number of pages14
JournalJournal of Glaciology
Issue number254
Publication statusPublished - 7 Oct 2019


  • RCUK
  • NERC
  • NE/I027576/1
  • NE/I025263/1


Dive into the research topics of 'Testing and application of a model for snow redistribution (Snow_Blow) in the Ellsworth Mountains, Antarctica'. Together they form a unique fingerprint.

Cite this