Severe convective storms in limited instability organized by pattern and distribution

IF 3 3区 地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES Weather and Forecasting Pub Date : 2023-12-26 DOI:10.1175/waf-d-23-0130.1
Trevor A. Campbell, G. Lackmann, Maria J. Molina, Matthew D. Parker
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Abstract

Severe convection occurring in high-shear, low-CAPE (HSLC) environments is a common cool-season threat in the Southeastern United States. Previous studies of HSLC convection document the increased operational challenges that these environments present compared to their high-CAPE counterparts, corresponding to higher false-alarm ratios and lower probability of detection for severe watches and warnings. These environments can exhibit rapid destabilization in the hours prior to convection, sometimes associated with the release of potential instability. Here, we use self-organizing maps (SOMs) to objectively identify environmental patterns accompanying HSLC cool season severe events and associate them with variations in severe weather frequency and distribution. Large scale patterns exhibit modest variation within the HSLC subclass, featuring strong surface cyclones accompanied by vigorous upper-tropospheric troughs and northward-extending regions of instability, consistent with prior studies. In most patterns, severe weather occurs immediately ahead of a cold front. Other convective ingredients, such as lower-tropospheric vertical wind shear, near-surface equivalent potential temperature (θe) advection, and the release of potential instability, varied more significantly across patterns. No single variable used to train SOMs consistently demonstrated differences in the distribution of severe weather occurrence across patterns. Comparison of SOMs based on upper and lower quartiles of severe occurrence demonstrated that the release of potential instability was most consistently associated with higher-impact events in comparison to other convective ingredients. Overall, we find that previously developed HSLC composite parameters reasonably identify high-impact HSLC events.
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按模式和分布组织的有限不稳定性中的强对流风暴
发生在高切变、低CAPE(HSLC)环境中的强对流是美国东南部冷季常见的威胁。以往对 HSLC 对流的研究表明,与高 CAPE 环境相比,这些环境带来的运行挑战更大,相应的误报率更高,严重天气监视和警报的探测概率更低。这些环境在对流发生前的几个小时内会表现出快速的不稳定,有时还与潜在不稳定性的释放有关。在此,我们使用自组织地图(SOM)客观地识别伴随 HSLC 冷季严重事件的环境模式,并将它们与严重天气频率和分布的变化联系起来。大尺度模式在 HSLC 亚类中表现出适度的变化,其特点是强表面气旋伴随着强烈的上对流层槽和向北延伸的不稳定区域,这与之前的研究一致。在大多数模式中,恶劣天气会紧接着冷锋出现。其他对流成分,如低对流层垂直风切变、近地表等效潜在温度(θe)平流和潜在不稳定性的释放,在不同模式中的变化更为显著。用于训练 SOM 的单个变量在不同模式的恶劣天气发生分布方面都没有持续的差异。基于严重天气发生率上下限四分位数的 SOMs 比较表明,与其他对流成分相比,潜在不稳定性的释放与影响较大的事件关联最为一致。总之,我们发现以前开发的 HSLC 复合参数可以合理地识别高影响 HSLC 事件。
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来源期刊
Weather and Forecasting
Weather and Forecasting 地学-气象与大气科学
CiteScore
5.20
自引率
17.20%
发文量
131
审稿时长
6-12 weeks
期刊介绍: Weather and Forecasting (WAF) (ISSN: 0882-8156; eISSN: 1520-0434) publishes research that is relevant to operational forecasting. This includes papers on significant weather events, forecasting techniques, forecast verification, model parameterizations, data assimilation, model ensembles, statistical postprocessing techniques, the transfer of research results to the forecasting community, and the societal use and value of forecasts. The scope of WAF includes research relevant to forecast lead times ranging from short-term “nowcasts” through seasonal time scales out to approximately two years.
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