2018年4月6日至7日VORTEX-SE期间洛杉矶门罗龙卷风超级单元的气压、水平涡度和中气旋演化之间的关系

IF 2.8 3区 地球科学 Q3 METEOROLOGY & ATMOSPHERIC SCIENCES
Michael J. Hosek, Conrad L. Ziegler, M. Biggerstaff, Todd A. Murphy, Zhien Wang
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引用次数: 0

摘要

本案例分析了2018年4月6日至7日在路易斯安那州东北部观测到的龙卷风超级单体,这是对东南龙卷风实验(VORTEX-SE)旋转起源验证的一部分。一台移动研究雷达(SR1-P)、一台WSR-88D等效雷达(KULM)和两台机载雷达(TAFT和TFOR)近距离对风暴进行了约70分钟的采样,包括成熟阶段、2340 UTC的龙卷风形成、消散和随后进入发展中的MCS段。从4多普勒分析得到的4-D风场和反射率,结合4-D非绝热拉格朗日分析(DLA, Ziegler 2013a,b)反演,可以对nws观测的EF-0龙卷风消散前、消散期间和消散后的风暴尺度边界进行运动学和热力学分析。运动学和热力学分析表明,低水平的流向涡度瞬态流导致了低水平的超级单体上升气流,这与超级单体模拟中发现的流向涡度流(SVC)相似,之前仅在运动学上观察到。涡度动力学计算表明,斜压性和水平伸展在与此SVC相关的流向涡度的产生和放大中起重要作用。虽然SVC不直接为龙卷风气旋提供流向涡度,但它的发展与龙卷风形成和超级单体主要低层上升气流的增强同时发生,尽管因果关系尚不清楚。虽然中尺度环境不是高切变/低cape (HSLC),但所分析的超级单体的上升气流与过去对美国东南部高切变/低cape风暴的观测和模拟有一些相似之处,最明显的是在风暴的中低层最大的脉冲状上升气流。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Relation Between Baroclinity, Horizontal Vorticity, and Mesocyclone Evolution in the 6-7 April 2018 Monroe, LA Tornadic Supercell During VORTEX-SE
This case study analyzes a tornadic supercell observed in northeast Louisiana as part of the Verification of the Origins of Rotation in Tornadoes Experiment Southeast (VORTEX-SE) on April 6-7 2018. One mobile research radar (SR1-P), one WSR-88D equivalent (KULM), and two airborne radars (TAFT and TFOR) have sampled the storm at close proximity for ~70 minutes through its mature phase, tornadogenesis at 2340 UTC, and dissipation and subsequent ingestion into a developing MCS segment. The 4-D wind field and reflectivity from up to four-Doppler analyses, combined with 4-D diabatic Lagrangian analysis (DLA, Ziegler 2013a,b) retrievals, has enabled kinematic and thermodynamic analysis of storm-scale boundaries leading up to, during, and after the dissipation of the NWS-surveyed EF-0 tornado. The kinematic and thermodynamic analyses reveal a transient current of low-level streamwise vorticity leading into the low-level supercell updraft, appearing similar to the streamwise vorticity current (SVC) that has been identified in supercell simulations and previously observed only kinematically. Vorticity dynamical calculations demonstrate that both baroclinity and horizontal stretching play significant roles in the generation and amplification of streamwise vorticity associated with this SVC. While the SVC does not directly feed streamwise vorticity to the tornado-cyclone, its development coincides with tornadogenesis and an intensification of the supercell’s main low-level updraft, although a causal relationship is unclear. Although the mesoscale environment is not high-shear/low-CAPE (HSLC), the updraft of the analyzed supercell shares some similarities to past observations and simulations of HSLC storms in the Southeast US, most notably a pulse-like updraft which is maximized in the low to mid-levels of the storm.
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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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