![\"\"](\"https:\/\/cimss.ssec.wisc.edu\/satellite-blog\/images\/2024\/05\/240508_goes16_visible_infrared_glmFlashExtentDensity_warningPolygons_TN_anim.gif\")
<\/a>1-minute GOES-16 \u201cRed\u201d Visible (0.64 \u00b5m, top) and \u201cClean\u201d Infrared Window (10.3 \u00b5m, bottom) images with plots of Severe Thunderstorm Warning (yellow) and Tornado Warning (red) polygons — with\/without an overlay of GLM Flash Extent Density — from 2059 UTC on 08 May to 0000 UTC on 09 May [click to play animated GIF | MP4<\/strong><\/a>]<\/p><\/div>1-minute\u00a0Mesoscale Domain Sector<\/strong><\/a>\u00a0GOES-16\u00a0(GOES-East)<\/em> \u201cRed\u201d Visible (0.64 \u00b5m<\/strong><\/a>) and \u201cClean\u201d Infrared Window (10.3 \u00b5m<\/strong><\/a>) images\u00a0(above)<\/strong><\/em> included plots of Severe Thunderstorm Warning and Tornado Warning polygons — which showed the supercell thunderstorm that produced EF3 damage and was responsible for 1 fatality in the Columbia area (just southwest of Nashville) on 08 May 2024<\/strong><\/a> (SPC Storm Reports<\/strong><\/a>). Pulses of thunderstorm overshooting tops were evident in the Visible and Infrared imagery. One sequence of the images also included an overlay of GOES-16 GLM<\/strong><\/a>\u00a0Flash Extent Density<\/strong><\/a> — which revealed a few brief lightning jumps (the peak Flash Extent Density rate was 172 at 2156 UTC<\/strong><\/a>).<\/p>\n 1-minute GOES-16 Visible\/Infrared Sandwich RGB<\/strong><\/a>\u00a0images\u00a0(below)<\/strong><\/em> began to exhibit an Above-Anvil Cirrus Plume or AACP (reference<\/strong><\/a>\u00a0|\u00a0VISIT training<\/strong><\/a> | blog posts<\/strong><\/a>) about an hour before the tornado began near Columbia around 2237 UTC (damage survey<\/strong><\/a>). A Tornado Emergency (bold red polygon) was then issued for the Spring Hill area (and downstream locations) at 2253 UTC<\/strong><\/a>.<\/p>\n 1-minute GOES-16 Visible\/Infrared Sandwich RGB images with plots of Severe Thunderstorm Warning (yellow) and Tornado Warning (red) polygons, from 2059-2300 UTC on 08 May [click to play animated GIF | MP4<\/strong><\/a>]<\/p><\/div>\n GOES-16 \u201cRed\u201d Visible (0.64 \u00b5m, top) and \u201cClean\u201d Infrared Window (10.3 \u00b5m, bottom) images with plots of Severe Thunderstorm Warning (yellow) and Tornado Warning polygons (red) at 2143 UTC on 08 May [click to enlarge]<\/p><\/div>As the AACP was becoming established, the cloud-top cold\/warm couplet infrared brightness temperature values at 2143 UTC<\/strong><\/a> were -72.1\u00baC\/-49.1\u00baC (darker black enhancement\/brighter green enhancement), respectively (above)<\/strong><\/em>. According to a plot (source<\/strong><\/a>) of rawinsonde data<\/strong><\/a> from Nashville, Tennessee at 1800 UTC on 08 May (below)<\/strong><\/em>, the -72.1\u00baC value represented a significant (~1 km) overshoot of the Most Unstable (MU) air parcel Equilibrium Level (EL) value of -60.9\u00baC.<\/p>\n Plot of rawinsonde data from Nashville, Tennessee at 1800 UTC on 08 May [click to enlarge]<\/p><\/div>In a comparison of cursor-sampled GOES-16 \u201cClean\u201d Infrared Window (10.3 \u00b5m) infrared brightness temperature along with the corresponding Cloud Top Temperature<\/strong><\/a> and Cloud Top Height<\/strong><\/a> derived products for the cloud-top cold\/warm couplet at 2143 UTC (below)<\/strong><\/em>, there was an even greater range in Cloud Top Temperature values (-75.5\u00baC vs -47.4\u00baC), at Cloud Top Height values of 44222 ft (13.5 km) and 37757 ft (11.5 km), respectively. This implied that the small cluster of warm pixels immediately downwind of the cold overshooting top represented a ~6465 ft (2.0 km) depression of the cloud-top topography (likely a result of compensating subsidence).<\/p>\n<\/a><\/a><\/a>