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- Title
Comparative Analysis of Energy Characteristics of Two Southwest Vortices in Sichuan Under Similar Circulation Backgrounds.
- Authors
ZHOU Chun-hua; ZHANG Ju; XIAO Hong-ru
- Abstract
Based on ERA5 reanalysis data, the present study analyzed the thermal energy development mechanism and kinetic energy conversion characteristics of two extreme rainstorm processes in relation to the shallow southwest vortex in the warm-sector during a "rain-generated vortex" process and the deep southwest vortex in a "vortex-generated rain" process. The findings were as follows: (1) During the extreme rainstorm on August 11, 2020 (hereinafter referred to as the "8·11" process), intense surface heating and a high-energy unstable environment were observed. The mesoscale convergence system triggered convection to produce heavy rainfall, and the release of latent condensation heat generated by the rainfall promoted the formation of a southwest vortex. The significant increase (decrease) in atmospheric diabatic heating and kinetic energy preceded the increase (decrease) in vorticity. By contrast, the extreme rainstorm on August 16, 2020 (hereinafter referred to as the "8·16" process) involved the generation of southwest vortex in a low-energy and highhumidity environment. The dynamic uplift of the southwest vortex triggered rainfall, and the release of condensation latent heat from rainfall further strengthened the development of the southwest vortex. The significant increase (decrease) in atmospheric diabatic heating and kinetic energy exhibited a delayed progression compared to the increase (decrease) in vorticity. (2) The heating effect around the southwest vortex region was non-uniform, and the heating intensity varied in different stages. In the "8·11" process, the heating effect was the strongest in the initial stage, but weakened during the vortex's development. On the contrary, the heating effect was initially weak in the "8·16" process, and intensified during the development stage. (3) The available potential energy of the "8·11" process significantly increased in kinetic energy converted from rotational and divergent winds through baroclinic action, and the divergent wind energy continued to convert into rotational wind energy. By contrast, the "8·16" process involved the conversion of rotational wind energy into divergent wind energy, which in turn converted kinetic energy back into available potential energy, thereby impeding the further development and maintenance of the southwest vortex.
- Subjects
SICHUAN Sheng (China); RAINSTORMS; KINETIC energy; WIND power; ENERGY development; LATENT heat; COMPARATIVE studies
- Publication
Journal of Tropical Meteorology, 2024, Vol 30, Issue 2, p168
- ISSN
1006-8775
- Publication type
Article
- DOI
10.3724/j.1006-8775.2024.015