Environmental and Storm-Scale Controls on Close Proximity Supercells Observed by TORUS on 8 June 2019

IF 2.8 3区地球科学 Q3 METEOROLOGY & ATMOSPHERIC SCIENCES

Monthly Weather Review Pub Date : 2023-09-20 DOI:10.1175/mwr-d-23-0002.1

Matthew B. Wilson, Adam L. Houston, Conrad L. Ziegler, Daniel M. Stechman, Brian Argrow, Eric W. Frew, Sara Swenson, Erik Rasmussen, Michael Coniglio

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引用次数: 0

Abstract

Abstract The Targeted Observation by Radars and UAS of Supercells (TORUS) field project observed two supercells on 8 June 2019 in northwestern Kansas and far eastern Colorado. Although these storms occurred in close spatial and temporal proximity, their evolutions were markedly different. The first storm struggled to maintain itself and eventually dissipated. Meanwhile, the second supercell developed just after and slightly to the south of where the first storm dissipated, and then tracked over almost the same location before rapidly intensifying and going on to produce several tornadoes. The objective of this study is to determine why the first storm struggled to survive and failed to produce mesocyclonic tornadoes while the second storm thrived and was cyclically tornadic. Analysis relies on observations collected by the TORUS project–including UAS transects and profiles, mobile soundings, surface mobile mesonet transects, and dual-Doppler wind syntheses from the NOAA P-3 tail Doppler radars. Our results indicate that rapid changes in the low-level wind profile, the second supercell’s interaction with two mesoscale boundaries, an interaction with a rapidly-intensifying new updraft just to its west, and the influence of a strong outflow surge likely account for much of the second supercell’s increased strength and tornado production. The rapid evolution of the low-level wind profile may have been most important in raising the probability of the second supercell becoming tornadic, with the new updraft and the outflow surge leading to a favorable storm-scale evolution that increased this probability further.

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2019年6月8日TORUS观测到的近距离超级单体的环境和风暴规模控制

2019年6月8日，美国堪萨斯州西北部和科罗拉多州远东地区的“超级单体”(TORUS)野外雷达与无人机目标观测项目对两个超级单体进行了观测。虽然这些风暴在空间和时间上都很接近，但它们的演变却有明显的不同。第一场风暴努力维持，最终消散。与此同时，第二个超级单体在第一场风暴消散的地方稍向南发展，然后在几乎相同的位置形成，然后迅速增强并继续产生几次龙卷风。本研究的目的是确定为什么第一场风暴难以生存并未能产生中气旋龙卷风，而第二场风暴却蓬勃发展并形成了周期性龙卷风。分析依赖于TORUS项目收集的观测数据，包括UAS横断面和剖面图、移动探测、地面移动中网横断面和NOAA P-3尾部多普勒雷达的双多普勒风合成。我们的研究结果表明，低层风廓线的快速变化，第二个超级单体与两个中尺度边界的相互作用，与其西面快速增强的新上升气流的相互作用，以及强烈的流出浪涌的影响可能是第二个超级单体强度增加和龙卷风产生的主要原因。低层风廓线的快速演变可能是提高第二个超级单体成为龙卷风的可能性的最重要因素，新的上升气流和流出浪涌导致有利的风暴尺度演变，进一步增加了这种可能性。

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来源期刊

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.