The impact of surface drag on the structure and evolution of surface boundaries associated with tornadogenesis in simulated supercells

IF 2.8 3区 地球科学 Q3 METEOROLOGY & ATMOSPHERIC SCIENCES
Qin Jiang, Daniel T. Dawson
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引用次数: 0

Abstract

Abstract Surface boundaries in supercells have been suspected of being important in the arrangement and concentration of vorticity for the development and intensification of tornadoes, but there has been little attention given to the effects of the underlying surface roughness on their behavior. This study investigates the impact of surface drag on the structure and evolution of these boundaries, their associated distribution of near-surface vorticity, and tornadogenesis and maintenance. Comparisons between idealized simulations without and with drag introduced in the mature stage of the storm prior to tornadogenesis reveal that the inclusion of surface drag substantially alters the low-level structure, particularly with respect to the number, location, and intensity of surface convergence boundaries. Substantial drag-generated horizontal vorticity induces rotor structures near the surface associated with the convergence boundaries in both the forward and rear flanks of the storm. Stretching of horizontal vorticity and subsequent tilting into the vertical along the convergence boundaries lead to elongated positive vertical vorticity sheets on the ascending branch of the rotors and the opposite on the descending branch. The larger near-surface pressure deficit associated with the faster development of the near-surface cyclone when drag is active creates a downward dynamic vertical pressure gradient force that suppresses vertical growth, leading to a weaker and wider tornado detached from the surrounding convergence boundaries. A conceptual model of the low-level structure of the tornadic supercell is presented that focuses on the contribution of surface drag, with the aim of adding more insight and complexity to previous conceptual models.
模拟超级单体中与龙卷风形成有关的表面阻力对表面边界结构和演化的影响
人们一直怀疑超级单体的表面边界在龙卷风的发展和增强中对涡度的排列和集中起着重要作用,但很少有人关注下垫表面粗糙度对龙卷风行为的影响。本文研究了地表阻力对这些边界的结构和演化的影响,以及与之相关的近地表涡度分布,以及龙卷风的形成和维持。在龙卷风形成前的风暴成熟阶段引入阻力和不引入阻力的理想模拟之间的比较表明,表面阻力的加入极大地改变了低层结构,特别是在地面辐合边界的数量、位置和强度方面。大量的阻力产生的水平涡度诱导了与风暴前后侧翼辐合边界相关的表面附近的转子结构。水平涡度的拉伸以及随后沿辐合边界向垂直方向倾斜导致旋翼上升分支的垂直正涡度片拉长,而下降分支的垂直正涡度片则相反。当阻力活跃时,更大的近地面压力赤字与近地面气旋的更快发展有关,产生了向下的动态垂直压力梯度力,抑制了垂直增长,导致龙卷风从周围辐合边界分离出来,强度更弱,范围更广。本文提出了一个龙卷风超级单体低层结构的概念模型,该模型主要关注地表阻力的作用,目的是在原有概念模型的基础上增加更多的洞察力和复杂性。
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来源期刊
Monthly Weather Review
Monthly Weather Review 地学-气象与大气科学
CiteScore
6.40
自引率
12.50%
发文量
186
审稿时长
3-6 weeks
期刊介绍: Monthly Weather Review (MWR) (ISSN: 0027-0644; eISSN: 1520-0493) publishes research relevant to the analysis and prediction of observed atmospheric circulations and physics, including technique development, data assimilation, model validation, and relevant case studies. This research includes numerical and data assimilation techniques that apply to the atmosphere and/or ocean environments. MWR also addresses phenomena having seasonal and subseasonal time scales.
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