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Mesoscale Dynamics and Its Application in Torrential Rainfall Systems in China 被引量:4

Mesoscale Dynamics and Its Application in Torrential Rainfall Systems in China
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摘要 Progress over the past decade in understanding moisture-driven dynamics and torrential rain storms in China is reviewed in this paper. First, advances in incorporating moisture effects more realistically into theory are described, including the development of a new parameter, generalized moist potential vorticity(GMPV) and an improved moist ageostrophic Q vector(Qum). Advances in vorticity dynamics are also described, including the adoption of a "parcel dynamic" approach to investigate the development of the vertical vorticity of an air parcel; a novel theory of slantwise vorticity development, proposed because vorticity develops easily near steep isentropic surfaces; and the development of the convective vorticity vector(CVV)as an effective new tool. The significant progress in both frontal dynamics and wave dynamics is also summarized, including the geostrophic adjustment of initial unbalanced flow and the dual role of boundary layer friction in frontogenesis, as well as the interaction between topography and fronts, which indicate that topographic perturbations alter both frontogenesis and frontal structure. For atmospheric vortices, mixed wave/vortex dynamics has been extended to explain the propagation of spiral rainbands and the development of dynamical instability in tropical cyclones. Finally, we review wave and basic flow interaction in torrential rainfall, for which it was necessary to extend existing theory from large-scale flows to mesoscale fields, enriching our knowledge of mesoscale atmospheric dynamics. Progress over the past decade in understanding moisture-driven dynamics and torrential rain storms in China is reviewed in this paper. First, advances in incorporating moisture effects more realistically into theory are described, including the development of a new parameter, generalized moist potential vorticity(GMPV) and an improved moist ageostrophic Q vector(Qum). Advances in vorticity dynamics are also described, including the adoption of a "parcel dynamic" approach to investigate the development of the vertical vorticity of an air parcel; a novel theory of slantwise vorticity development, proposed because vorticity develops easily near steep isentropic surfaces; and the development of the convective vorticity vector(CVV)as an effective new tool. The significant progress in both frontal dynamics and wave dynamics is also summarized, including the geostrophic adjustment of initial unbalanced flow and the dual role of boundary layer friction in frontogenesis, as well as the interaction between topography and fronts, which indicate that topographic perturbations alter both frontogenesis and frontal structure. For atmospheric vortices, mixed wave/vortex dynamics has been extended to explain the propagation of spiral rainbands and the development of dynamical instability in tropical cyclones. Finally, we review wave and basic flow interaction in torrential rainfall, for which it was necessary to extend existing theory from large-scale flows to mesoscale fields, enriching our knowledge of mesoscale atmospheric dynamics.
出处 《Advances in Atmospheric Sciences》 SCIE CAS CSCD 2015年第2期192-205,共14页 大气科学进展(英文版)
基金 supported by the National Natural Science Foundation of China (Grant Nos. 91437215 and 41375052) State Key Laboratory of Severe Weather Open Project (Grant No. 2013LASW-A06) the Key Research Program of the Chinese Academy of Sciences (Grant No. KZZD-EW05-01)
关键词 mesoscale dynamics torrential rainfall moist atmosphere vorticity dynamics wave-flow interaction mesoscale dynamics,torrential rainfall,moist atmosphere,vorticity dynamics,wave-flow interaction
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  • 1汪克付,叶金印.江淮梅雨锋暴雨过程Q矢量分析及落区预报[J].气象,1995,21(3):40-43. 被引量:15
  • 2吴国雄,蔡雅萍,唐晓菁.湿位涡和倾斜涡度发展[J].气象学报,1995,53(4):387-405. 被引量:639
  • 3费建芳,陆汉城.圆形涡旋中的惯性重力内波不稳定和对称不稳定[J].大气科学,1996,20(1):54-62. 被引量:15
  • 4Anthes, R. A., 1982: Tropical Cyclones: Their Evolution, Structure and Effect. Amer. Meteor. Soc., Boston, MA, USA, 208pp.
  • 5Charney, J. G., 1947: The dynamics of long waves in a baroclinic westerly current. J. Meteor., 4, 135-163.
  • 6v - Eady, E. T., 1949: Long waves and cyclone waves. Tellus, 1, 33-52.
  • 7Eliassen, A., 1952: Slow thermally or frictionally controlled meridional circulation in a circular vortex. Astrophysica Norvegica, 5, 19-60.
  • 8Emanuel, K. A., 1995: The behavior of a simple hurricane model using a convective scheme based on subcloudlayer entropy equilibrium. J. Atmos. Sci., 52, 3960- 3968.
  • 9Frederiksen, J. S., 1979: The effects of long planetary waves on the regional cyclogenesis. J. Atmos. Sci., 36, 195-204.
  • 10Kuo, H. L., and B. C. Zhu, 1981: Atmospheric Dynamics. Chinese Science and Technology Press of Jiangsu, Jiangsu, China, 48pp.

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