Abstract
Energy budgets were analyzed to study the development of an eastward propagating southwest vortex (SWV) associated with heavy rainfall over southern China (11–13 June 2008). The results show that kinetic energy (KE) generation and advection were the most important KE sources, while friction and sub-grid processes were the main KE sinks. There was downward conversion from divergent to rotational wind KE consistent with the downward stretching of SWVs. The Coriolis force was important for the formation and maintenance of the SWV. Convergence was also an important factor for maintenance, as was vertical motion during the mature stage of the SWV and the formation stage of a newly formed vortex (vortex B). The conversion from available potential energy (APE) to KE of divergent wind can lead to strong convection. Vertical motion influenced APE by dynamical and thermal processes which had opposite effects. The variation of APE was related to the heavy rainfall and convection; in this case, vertical motion with direct thermal circulation was the most important way in which APE was released, while latent heat release and vertical temperature advection were important for APE generation.
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Fu, S., Sun, J., Zhao, S. et al. The energy budget of a southwest vortex with heavy rainfall over south China. Adv. Atmos. Sci. 28, 709–724 (2011). https://doi.org/10.1007/s00376-010-0026-z
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DOI: https://doi.org/10.1007/s00376-010-0026-z