![\"GOES-16](\"https:\/\/cimss.ssec.wisc.edu\/satellite-blog\/wp-content\/uploads\/sites\/5\/2019\/03\/wy_wv9-20190311_090212.png\")
<\/a>GOES-16 Low-level (7.3 \u00b5m),<\/em> Mid-level (6.9 \u00b5m)<\/em> and Upper-level (6.2 \u00b5m)<\/em> Water Vapor images, with topography [click to play MP4<\/strong><\/a> animation]<\/p><\/div>GOES-16 (GOES-East)<\/em> Low-level (7.3 \u00b5m<\/strong><\/a>), Mid-level (6.9 \u00b5m<\/strong><\/a>) and Upper-level (6.2 \u00b5m<\/strong><\/a>) Water Vapor images (above)<\/strong><\/em> revealed a narrow filament of dry air over northern Wyoming and western South Dakota on the morning of 11 March 2019. A cold thermal signature of the Bighorn Mountains<\/strong><\/a> in northern Wyoming could be seen through this band of dry air — even on the Upper-level 6.2 \u00b5m imagery.<\/p>\n At 12 UTC<\/strong><\/a> the Rapid City SD (KUNR<\/strong><\/a>) sounding sampled this filament of dry air, but the Riverton WY (KRIW<\/strong><\/a>) sounding — even though it was closer to the Bighorn Mountains — did not, due to the presence of moist air throughout much of the middle\/upper-troposphere over southern and central Wyoming. As a result, the Rapid City water vapor weighting functions<\/strong><\/a> peaked at a lower altitude than those for Riverton (below)<\/strong>,<\/em> thus enabling the Bighorn Mountain thermal signature to be seen. In the animation above, note how the mountain signature eventually became masked, especially in the 6.9 \u00b5m and 6.2 \u00b5m imagery, as the middle\/upper-tropospheric moisture moved slowly northward during the day. As was the case over Riverton at 12 UTC, this high-altitude moisture absorbed upwelling surface radiation, then re-radiated it at the colder ambient temperature of the atmospheric layer where it existed.<\/p>\n GOES-16 Water Vapor weighting functions, calculated using rawinsonde data from Rapid City SD and Riverton WY [click to enlarge]<\/p><\/div> GOES-17 and GOES-16 Upper-level Water Vapor (6.2 \u00b5m)<\/em> images [click to enlarge]<\/p><\/div>A toggle between 6.2 \u00b5m Water Vapor images from GOES-17 (GOES-West)<\/em> and GOES-16 at 1202 UTC\u00a0 (above)<\/strong><\/em> showed that while the filament of dry air appeared very similar from both satellites, there was a bit of noise in the GOES-17 image. In a plot of the mean 6.2 \u00b5m brightness temperature difference between GOES-17 and GOES-16 (below)<\/strong>,<\/em> note that the difference began to increase shortly before 12 UTC as GOES-17 ABI Loop Heat Pipe<\/strong><\/a> cooling issues started to adversely affect instrument performance. The GOES-17\/GOES-16 brightness temperature difference and GOES-17 ABI Focal Plane Module temperature can be monitored in real time here<\/strong><\/a>.<\/p>\n![\"GOES-16](\"https:\/\/cimss.ssec.wisc.edu\/satellite-blog\/wp-content\/uploads\/sites\/5\/2019\/03\/190311_12utc_kunr_kriw_waterVapor_weightingFunctions_anim.gif\")
<\/a>![\"GOES-17](\"https:\/\/cimss.ssec.wisc.edu\/satellite-blog\/wp-content\/uploads\/sites\/5\/2019\/03\/190311_1202utc_goes17_vs_goes16_waterVapor_WY_SD_anim.gif\")
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![\"Plot](\"https:\/\/cimss.ssec.wisc.edu\/satellite-blog\/wp-content\/uploads\/sites\/5\/2019\/03\/GOES17_FPMTemp_GOES16vsGOES17MeanDiff_CONUS_2019070_120218_Band08.png\")
<\/a>![\"Rapid](\"https:\/\/cimss.ssec.wisc.edu\/satellite-blog\/wp-content\/uploads\/sites\/5\/2019\/03\/190311_12utc_kunr_waterVapor_weightingFunctions_goes16_vs_goes17_anim.gif\")
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