Editorial Type:
Article
Article Type:
Research Article

On the Effects of Large-Scale Environment and Surface Types on Convective Cloud Characteristics over Darwin, Australia

Vickal V. Kumar * School of Mathematical Sciences, Monash University, and Centre for Australian Weather and Climate Research,** Melbourne, Victoria, Australia

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Alain Protat Centre for Australian Weather and Climate Research, Melbourne, Victoria, Australia

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Peter T. May Centre for Australian Weather and Climate Research, Melbourne, Victoria, Australia

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Christian Jakob School of Mathematical Sciences, Monash University, Melbourne, Victoria, Australia

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Guillaume Penide Université Sciences et Technologie de Lille, UFR de Physique Bâtiment P5 Laboratoire d’optique Atmosphérique, Lille, France

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Sushil Kumar School of Engineering and Physics, The University of the South Pacific, Fiji Islands

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Laura Davies School of Mathematical Sciences, Monash University, Melbourne, Victoria, Australia

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Print Publication:
01 Apr 2013
DOI:
https://doi.org/10.1175/MWR-D-12-00160.1
Page(s):
1358–1374
Restricted access

Abstract

Two seasons of Darwin, Australia, C-band polarimetric (CPOL) research radar, radiosoundings, and lightning data are examined to study the relative influence of the large-scale atmospheric regimes and the underlying surface types on tropical convective cloud properties and their diurnal evolution. The authors find that in the “deep westerly” regime, which corresponds to the monsoon period, the convective cloud occurrence rate is highest, consistent with its highest relative humidity. However, these convective clouds have relatively low cloud-top heights, smaller-than-average cell volumes, and are electrically least active. In this regime, the cloud cell volume does not vary significantly across different underlying surfaces and afternoon convective activity is suppressed. Thus, the picture emerging is that the convective cloud activity in the deep westerly regime is primarily regulated by the large-scale conditions. The remaining regimes (“easterly,” “shallow westerly,” and “moist easterly”) also demonstrate strong dependence on the large-scale forcing and a secondary dependence on the underlying surface type. The easterly regime has a small convective cloud occurrence rate and low cloud heights but higher lightning counts per convective cloud. The other two regimes have moderate convective cloud occurrence rates and larger cloud sizes. The easterly, shallow westerly, and moist easterly regimes exhibit a strong, clearly defined semidiurnal convective cloud occurrence pattern, with peaks in the early morning and afternoon periods. The cell onset times in these three regimes depend on the combination of local time and the underlying surface.

The Centre for Australian Weather and Climate Research is a partnership between the Bureau of Meteorology and the Commonwealth Scientific and Industrial Research Organisation.

Corresponding author address: Vickal V. Kumar, Centre for Australian Weather and Climate Research, Australian Bureau of Meteorology and CSIRO, GPO Box 1289, Melbourne 3001, Australia. E-mail: v.kumar@bom.gov.au

Abstract

Two seasons of Darwin, Australia, C-band polarimetric (CPOL) research radar, radiosoundings, and lightning data are examined to study the relative influence of the large-scale atmospheric regimes and the underlying surface types on tropical convective cloud properties and their diurnal evolution. The authors find that in the “deep westerly” regime, which corresponds to the monsoon period, the convective cloud occurrence rate is highest, consistent with its highest relative humidity. However, these convective clouds have relatively low cloud-top heights, smaller-than-average cell volumes, and are electrically least active. In this regime, the cloud cell volume does not vary significantly across different underlying surfaces and afternoon convective activity is suppressed. Thus, the picture emerging is that the convective cloud activity in the deep westerly regime is primarily regulated by the large-scale conditions. The remaining regimes (“easterly,” “shallow westerly,” and “moist easterly”) also demonstrate strong dependence on the large-scale forcing and a secondary dependence on the underlying surface type. The easterly regime has a small convective cloud occurrence rate and low cloud heights but higher lightning counts per convective cloud. The other two regimes have moderate convective cloud occurrence rates and larger cloud sizes. The easterly, shallow westerly, and moist easterly regimes exhibit a strong, clearly defined semidiurnal convective cloud occurrence pattern, with peaks in the early morning and afternoon periods. The cell onset times in these three regimes depend on the combination of local time and the underlying surface.

The Centre for Australian Weather and Climate Research is a partnership between the Bureau of Meteorology and the Commonwealth Scientific and Industrial Research Organisation.

Corresponding author address: Vickal V. Kumar, Centre for Australian Weather and Climate Research, Australian Bureau of Meteorology and CSIRO, GPO Box 1289, Melbourne 3001, Australia. E-mail: v.kumar@bom.gov.au
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