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A Tornado in South China in May 2015
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摘要: 利用常规观测、珠江三角洲区域自动气象站、广州多普勒天气雷达、深圳机场风廓线雷达及NCEP/NCAR等资料对2015年5月11日下午发生在深圳宝安机场附近的一次龙卷天气过程进行分析。结果表明:这次龙卷发生在500 hPa槽前、850 hPa切变线南侧以及地面冷锋的暖区一侧,上干冷、下暖湿的结构加剧了条件不稳定,环境对流有效位能很大,风垂直切变强,水汽丰富;产生龙卷的回波快速演变为逗点回波,出现钩状回波,龙卷发生在钩状回波内侧的弱回波区附近;与之对应的中气旋旋转速度不断加大,半径减小,并向低层发展。Abstract: A severe tornado event near Baoan International Airport of Shenzhen, Guangdong Province on 11 May 2015 is investigated. Based on the routine upper-air, surface automatic weather station (AWS), Doppler radar, wind profile data and NCEP 6-hour analysis data (1°×1°), the environmental condition, structure and evolution are analyzed. The intensity of this tornado belongs to the F1 tornado intensity category. The tornado event occurs in front of 500 hPa trough, warm and moist area ahead of 850 hPa shear lines and the warm section before surface cold front. It is significant that the atmospheric convective instability is strengthened by the low temperature and humidity increasing, and the dry cold air behind 500 hPa trough moving eastward. The calculation of atmospheric convective parameters shows that there is powerful convective available potential energy (CAPE), strong low-level vertical wind shear and abundant water vapor in atmospheric environment before the tornado occurs. The analysis of Doppler radar products also indicates that the storm has a life span lasting about 1 hour, during which its echo top extends the height of nearly 5 km. The tornado initially comes from a quasi-linear convective system along the surface convergence line. The quasi-linear convective system moves slowly down and becomes a massive comma echo, finally develops into hooked echo, and the tornado is detected near the weak echo area. The echo of the strongest center value reaches 62 dBZ. The tornado locates at the edge of the strongest echo gradient region near the weak echo region, which indicates that the strong updraft contributes most to the tornado. The mesocyclone first appears in the middle cell of the storm, beginning at 3 km height and then developing upward and downward. The height of the strong core (no less than 50 dBZ) is below 5 km in the tornado event, making it a low centroid convective system. The mesocyclone always shows cyclonic rotation characteristics from originated to maturity in the radial velocity chart. When the rotational speed increases, the radius of the mesocyclone decreases and the largest vertical vorticity associate with the mesocyclone is 1.2×10-2 s-1. The distance separating the strongest inbound and outbound radial velocities (called velocity couplet) is reduced from 8 km to 6 km. The mesocyclone deepens gradually downwards, producing the tornado. When the tornado is underway, strong divergence occurs at the storm top above the tornado. Therefore, in operational work more attention should be paid to the sudden change of echo shape and rapidly developing cyclone vortex.
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Key words:
- tornado;
- super cell;
- mesocyclone
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图 1 2015年5月11日深圳机场附近出现水龙卷
Fig. 1 The tornado lived near Shenzhen airport on 11 May 2015
图 2 2015年5月11日14:00 850 hPa风场 (风羽) 和水汽通量散度 (单位:10-5s-1)
(黑点为龙卷发生处)
Fig. 2 850 hPa wind (bard) and water vapor flux divergence (unit: 10-5s-1) at 1400 BT 11 May 2015
(the black point denotes the position of tornado)
图 3 2015年5月11日15:18和15:36广州雷达1.5°仰角反射率因子
(红圈所示为与发生龙卷对应的回波)
Fig. 3 Reflectivity from 1.5° elevation of Guangzhou radar at 1518 BT and 1536 BT on 11 May 2015
(the red circle shows the tornado corresponding echo)
图 4 2015年5月11日15:42广州雷达不同仰角反射率因子和径向速度图
(白色圆点为龙卷发生地,褐色圈为中气旋)
Fig. 4 Four-panel reflectivity and radial velocity of Guangzhou radar with different elevations centered on the supercell at 1542 BT 11 May 2015
(the tornado is marked by white point, the mesocyclone is marked by brown circle)
图 5 2015年5月11日15:12—16:00广州雷达中气旋顶高、底高及最大切变高度变化
Fig. 5 The change of base and top of mesocyclone with the strongest shear height from 1512 BT to 1600 BT on 11 May 2015 by Guangzhou radar
图 6 2015年5月11日广州雷达15:42反射率因子剖面图
Fig. 6 Vertical cross section of reflectivity of Guangzhou radar at 1542 BT 11 May 2015
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