![\"GOES-16](\"https:\/\/cimss.ssec.wisc.edu\/satellite-blog\/wp-content\/uploads\/sites\/5\/2017\/06\/958x638_GOES16A_B213_G16_VIS_IR_MESO_IL_WI_SVR_14JUN2017_2017165_195457_0002PANELS.GIF\")
<\/a>GOES-16 Visible (0.64 \u00b5m, left) and Infrared Window (10.3 \u00b5m, right) images, with station identifiers plotted in white and SPC storm reports plotted in cyan [click to play MP4 animation]<\/p><\/div>** GOES-16 data posted on this page are preliminary, non-operational data and are undergoing testing **<\/em><\/p>\n 1-minute interval Mesoscale Sector<\/strong><\/a> GOES-16 Visible (0.64 \u00b5m<\/strong><\/a>) and Infrared Window (10.3 \u00b5m<\/strong><\/a>) images (above)<\/strong> <\/em>showed the rapid development of convection across northern Illinois and southern Wisconsin on 14 June 2017<\/strong><\/a>. SPC storm reports<\/strong><\/a> indicated that these storms produced widespread hail, damaging winds and a few tornadoes.<\/p>\n GOES-16 Visible (0.64 \u00b5m) images [click to play MP4 animation]<\/p><\/div>Closer views centered along the Wisconsin\/Illinois border with Visible (0.64 \u00b5m) imagery (above)<\/strong> <\/em>showed the overshooting tops associated with these thunderstorms, while the Snow\/Ice (1.61 \u00b5m<\/strong><\/a>) imagery (below)<\/strong> <\/em>helped to discriminate between higher-altitude glaciated cloud tops (darker gray)<\/em> and lower-level cloud tops composed of supercooled water droplets (brighter white)<\/em>.<\/p>\n GOES-16 Snow\/Ice (1.61 \u00b5m) images [click to play MP4 animation]<\/p><\/div>The animation of Visible and color-enhanced Infrared imagery at the top of this blog post shows pockets of very cold cloud top temperatures within the cirrus canopy above the developing convection. These generally indicate overshooting tops, at the top of very strong updrafts. In contrast, the Shortwave Infrared (3.9 \u00b5m<\/strong><\/a>) animation, below, shows relatively warm<\/em> pixels that are darker in the grey-scale enhancement in about the same region. Why the difference? Ice crystals that emerge from the top of a strong updraft are very effective reflectors of solar radiation at a wavelength of 3.9 \u00b5m. The satellite detects both terrestrial 3.9 \u00b5m energy emitted from the cold cloud top and solar 3.9 \u00b5m energy reflected off the cloud top. The amount detected will be largest (and a warmer temperature is inferred) where ice crystals are smallest and most reflective: at the top of very strong updrafts. Very little solar 10.3 \u00b5m radiation is reflected off clouds.<\/p>\n GOES-16 Shortwave Infrared (3.90 \u00b5m) images [click to play MP4 animation]<\/p><\/div>All 16 bands on ABI can be used to monitor the development of the strong convection — in the case shown below over west-central Illinois for one hour, from 1900-2000 UTC. Click here for a very zoomed-in animation<\/a> over one cell!<\/p>\n![\"GOES-16](\"https:\/\/cimss.ssec.wisc.edu\/satellite-blog\/wp-content\/uploads\/sites\/5\/2017\/06\/170614_g16_vis.jpeg\")
<\/a>![\"GOES-16](\"https:\/\/cimss.ssec.wisc.edu\/satellite-blog\/wp-content\/uploads\/sites\/5\/2017\/06\/170614_g16_snow_ice.jpeg\")
<\/a>![\"GOES-16](\"https:\/\/cimss.ssec.wisc.edu\/satellite-blog\/wp-content\/uploads\/sites\/5\/2017\/06\/WI_STORM_B07_800x1000_B7_2017165_203257_0001PANEL.gif\")
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![\"GOES-16](\"https:\/\/cimss.ssec.wisc.edu\/satellite-blog\/wp-content\/uploads\/sites\/5\/2017\/06\/ABI_16P_2017165_IL_loop_2017165_190057_2017165_195957.jpg\")
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