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Effects of Vertically Propagating Mountain Waves During a Strong Wind Event Over the Ross Ice Shelf, Antarctica


Affiliations
1 Department of Geography, University of Malaya, Kuala Lumpur, Malaysia
2 British Antarctic Survey, Cambridge, United Kingdom
 

Weather forecasting in the Antarctic presents many challenges, with strong wind events (SWEs) often disrupting air and field operations. Here, we study the mechanisms responsible for a SWE (maximum wind speed 22 ms–1) that occurred at the McMurdo/Scott Base region on the Ross Ice Shelf (Antarctica) over 12–13 October 2003. The study is based on in situ observations, satellite imagery and output from the Antarctic mesoscale prediction system (AMPS) model. The event occurred during the passage of a complex low pressure system that increased the pressure gradient between the northwest Ross Ice Shelf and the continental high, initiating a strong southerly flow. AMPS simulations as well as upper air sounding profiles from McMurdo station showed the involvement of large amplitude vertically propagating mountain waves over the area. The amplification of mountain waves by the self-induced critical level reflected all the energy back towards the surface to generate high downslope winds.

Keywords

Katabatic Wind, Mesoscale Model, Mountain Wave, Strong Wind Events.
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  • Steinhoff, D. F., Bromwich, D. H., Lambertson, M., Knuth, S. L. and Lazzara, M. A., A dynamical investigation of the May 2004 McMurdo Antarctica severe wind event using AMPS. Mon. Wea. Rev., 2008, 136, 7–26; doi:10.1175/2007MWR1999.1.

  • Turner, J., Chenoli, S. N., Abu Samah, A., Marshall, G., Phillips, T. and Orr, A., Strong wind events in the Antarctic. J. Geophys. Res., 2009, 114, D18103; doi:10.1029/2008JD011642.

  • Chenoli, S. N., Turner, J. and Samah, A. A., A strong wind event on the Ross Ice Shelf, Antarctica: a case study of scale interactions. Mon. Wea. Rev., 2015, 143, 4163–4180.

  • Chenoli, S. N., Turner, J. and Samah, A. A., A climatology of strong wind events at McMurdo Station, Antarctica. Int. J. Climatol., 2012, 33, 2667–2681; doi:https://doi.org/10.1002/joc.3617

  • Dee, D. P. et al., The ERA-interim reanalysis: configuration and performance of the data assimilation system. QJR Meteorol. Soc., 2011, 137, 553–597.

  • Klemp, J. B. and Lilly, D. R., The dynamics of wave-induced downslope winds. J. Atmos. Sci., 1975, 32, 320–339.

  • Durran, D. R., Mountain waves, mesoscale meteorology and forecasting. Am. Meteorol. Soc., 1986, 472–492.


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  • Effects of Vertically Propagating Mountain Waves During a Strong Wind Event Over the Ross Ice Shelf, Antarctica

Abstract Views: 254  |  PDF Views: 90

Authors

Sheeba Nettukandy Chenoli
Department of Geography, University of Malaya, Kuala Lumpur, Malaysia
John Turner
British Antarctic Survey, Cambridge, United Kingdom
Azizan Abu Samah
Department of Geography, University of Malaya, Kuala Lumpur, Malaysia

Abstract


Weather forecasting in the Antarctic presents many challenges, with strong wind events (SWEs) often disrupting air and field operations. Here, we study the mechanisms responsible for a SWE (maximum wind speed 22 ms–1) that occurred at the McMurdo/Scott Base region on the Ross Ice Shelf (Antarctica) over 12–13 October 2003. The study is based on in situ observations, satellite imagery and output from the Antarctic mesoscale prediction system (AMPS) model. The event occurred during the passage of a complex low pressure system that increased the pressure gradient between the northwest Ross Ice Shelf and the continental high, initiating a strong southerly flow. AMPS simulations as well as upper air sounding profiles from McMurdo station showed the involvement of large amplitude vertically propagating mountain waves over the area. The amplification of mountain waves by the self-induced critical level reflected all the energy back towards the surface to generate high downslope winds.

Keywords


Katabatic Wind, Mesoscale Model, Mountain Wave, Strong Wind Events.

References





DOI: https://doi.org/10.18520/cs%2Fv115%2Fi9%2F1684-1689