The Severe Multi-Day October 2019 Snow Storm Over Southern Manitoba, Canada

IF 1.6 4区地球科学 Q4 METEOROLOGY & ATMOSPHERIC SCIENCES

Atmosphere-Ocean Pub Date : 2022-03-15 DOI:10.1080/07055900.2022.2060794

J. Hanesiak, R. Stewart, Dylan Painchaud-Niemi, S. Milrad, George Liu, M. Vieira, J. Thériault, Mélissa Cholette, Kyle Ziolkowski

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引用次数: 0

Abstract

ABSTRACT A devastating storm struck southern Manitoba, Canada on 10–13 October 2019, producing a large region of mainly sticky and wet snow. Accumulations reached 75 cm, wind gusts exceeded 100 km h−1, and surface temperature (T) remained near 0°C (−1°C ≤ T ≤ 1°C) for up to 88 h. It produced the largest October snowfall and was the earliest to produce at least 20 cm since 1872 in Winnipeg. These factors led to unparalleled damage and power restoration challenges for Manitoba Hydro and, with leaves still largely on vegetation, the most damaging storm to Winnipeg’s trees ever recorded. The storm’s track was uncommon, and produced elevated convection related to buoyancy-driven instability and conditional symmetric instability (CSI), with a moist absolutely unstable layer (MAUL) near 500 hPa. Instabilities were released via lift through lower-tropospheric warm advection and frontogenesis, differential cyclonic vorticity advection, and jet streak dynamics. Precipitation bands, elevated convection, and lake effect snow bands enhanced local snowfall. Snow adhering to structures was not always wet but, when present, it sometimes occurred because of incomplete freezing of particles partially melted aloft in a near-surface (<100 m deep) inversion. Although other storms over the historical record have produced a similar combination of severe precipitation, temperature and wind conditions, none have done this for such a long period.

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2019年10月加拿大马尼托巴南部持续多日的严重暴风雪

摘要2019年10月10日至13日，一场毁灭性风暴袭击了加拿大马尼托巴省南部，形成了一大片以黏湿雪为主的地区。累计达到75 厘米，阵风超过100 公里 h−1，表面温度（T）保持在0°C（−1°C ≤ T ≤ 1°C），最高可达88 h.它产生了10月份最大的降雪，也是最早产生至少20场降雪的自1872年以来在温尼伯。这些因素给马尼托巴水电公司带来了前所未有的破坏和电力恢复挑战，而且由于树叶仍大部分在植被上，这是有记录以来对温尼伯树木破坏最严重的风暴。风暴的路径并不常见，并产生了与浮力驱动的不稳定性和条件对称不稳定性（CSI）有关的对流上升，潮湿的绝对不稳定层（MAUL）接近500 百帕。不稳定是通过对流层低层暖平流和锋生、差分气旋涡度平流和喷流条纹动力学的升力释放的。降水带、对流增强和湖泊效应雪带增强了局部降雪。附着在结构上的雪并不总是潮湿的，但当存在时，有时会发生这种情况，因为在近表面的高空部分融化的颗粒不完全冻结（<100 m深）反转。尽管历史记录上的其他风暴也产生了类似的严重降水、温度和风力条件，但没有一场风暴在这么长的时间内产生这种情况。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Atmosphere-Ocean 地学-海洋学

CiteScore

2.50

自引率

16.70%

发文量

审稿时长

>12 weeks

期刊介绍： Atmosphere-Ocean is the principal scientific journal of the Canadian Meteorological and Oceanographic Society (CMOS). It contains results of original research, survey articles, notes and comments on published papers in all fields of the atmospheric, oceanographic and hydrological sciences. Arctic, coastal and mid- to high-latitude regions are areas of particular interest. Applied or fundamental research contributions in English or French on the following topics are welcomed: climate and climatology; observation technology, remote sensing; forecasting, modelling, numerical methods; physics, dynamics, chemistry, biogeochemistry; boundary layers, pollution, aerosols; circulation, cloud physics, hydrology, air-sea interactions; waves, ice, energy exchange and related environmental topics.