中层切变和水平旋涡对超级单体上升气流动力学的影响

IF 3 3区 地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES Journal of the Atmospheric Sciences Pub Date : 2023-11-14 DOI:10.1175/jas-d-23-0082.1
Andrew J. Muehr, James H. Ruppert, Matthew D. Flournoy, John M. Peters
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引用次数: 0

摘要

大中层剪切(3 ~ 6 km AGL)是超级单体环境中常见的剪切现象。然而,到目前为止,中层切变对上升气流的任何可能影响还相对未被探索。为了进行研究,我们在一系列具有不同中层剪切强度的环境中对超级单体进行了十次模拟。在大多数情况下,较大的中层切变导致风暴运动相对于低层涡图更快,这意味着较大的中层切变导致较强的低层风暴相对流。由于它们具有物理上的联系,我们分析了中层切变和低层风暴相对流对超级单体上升气流动力学的影响。较大的中层切变不会导致内聚上升气流旋转的增加。中层环境涡度的倾斜确实导致上升气流南缘的局部垂直涡度较大,但其任何动力学影响都被与旋翼状环流相关的同一区域的大得多的水平涡度所掩盖。当中层切变和低层风暴相对流较大时,风暴产生的水平涡度是中层上升气流南侧非线性动压较低的主要驱动因素,在这种情况下,非线性动压加速度较大。在中层上升气流中,除非中气旋变得特别强烈,否则风暴产生的水平涡度是造成最低非线性动压的原因。这些结果阐明了中层切变对超级单体雷暴的影响,并为低层风暴相对流对上升气流动力学的作用提供了额外的见解。
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The Influence of Midlevel Shear and Horizontal Rotors on Supercell Updraft Dynamics
Abstract Large midlevel (3–6 km AGL) shear is commonly observed in supercell environments. However, any possible influence of midlevel shear on an updraft has been relatively unexplored until now. To investigate, we ran ten simulations of supercells in a range of environments with varying midlevel shear magnitudes. In most cases, larger midlevel shear results in a storm motion that is faster relative to the low-level hodograph, meaning that larger midlevel shear leads to stronger low-level storm-relative flow. Because they are physically connected, we present an analysis of the effects of both midlevel shear and low-level storm-relative flow on supercell updraft dynamics. Larger midlevel shear does not lead to an increase in cohesive updraft rotation. The tilting of midlevel environmental vorticity does lead to localized areas of larger vertical vorticity on the southern edge of the updraft, but any dynamical influence of this is overshadowed by that of much larger horizontal vorticity in the same area associated with rotor-like circulations. This storm-generated horizontal vorticity is the primary driver behind lower nonlinear dynamic pressure on the southern flank of the midlevel updraft when midlevel shear and low-level storm-relative flow are larger, which leads to a larger nonlinear dynamic pressure acceleration in those cases. Storm-generated horizontal vorticity is responsible for the lowest nonlinear dynamic pressure anywhere in the midlevel updraft, unless the mesocyclone becomes particularly intense. These results clarify the influence of midlevel shear on a supercell thunderstorm, and provide additional insight on the role of low-level storm-relative flow on updraft dynamics.
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来源期刊
Journal of the Atmospheric Sciences
Journal of the Atmospheric Sciences 地学-气象与大气科学
CiteScore
0.20
自引率
22.60%
发文量
196
审稿时长
3-6 weeks
期刊介绍: The Journal of the Atmospheric Sciences (JAS) publishes basic research related to the physics, dynamics, and chemistry of the atmosphere of Earth and other planets, with emphasis on the quantitative and deductive aspects of the subject. The links provide detailed information for readers, authors, reviewers, and those who wish to submit a manuscript for consideration.
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