Shown below is a comparison of GOES-15 (GOES-West), GOES-14 and GOES-13 (GOES-East) Visible images covering the longer 1-hour period of 1230-1330 UTC, focusing on a area of thunderstorms over North Texas. During this time, there are 53 images from GOES-14, compared to 7 images from GOES-15 and 5 images from GOES-13 — note how the evolution of overshooting tops is very easy to follow using the 1-minute GOES-14 imagery.GOES-14 also monitored the dissipation of fog/low stratus clouds over Nebraska, as seen in the animation below. Additional details can be found here. Later in the day, the GOES-14 Visible (0.62 µm) animation below (also available as a large 62 Mbyte animated GIF) showed the development of severe thunderstorms in Montana and Wyoming, which produced several reports of damaging winds and large hail (up to 4.0 inches in diameter). This example is particularly noteworthy due to the fact that the storm was well-sampled by satellite imagery in a region of poor radar coverage (h/t to @DanLindsey77). For additional details on this case, see the VISIT Meteorological Interpretation Blog. A 3-panel comparison of Visible images from GOES-15 and GOES-13 (available at the routine 15-30 minute interval) and GOES-14 (available at 1-minute intervals) is shown below. During the early afternoon hours, the GOES-15 (GOES-West) satellite performed a “North/South Station Keeping maneuver”, during which there was no imaging between 1700-1900 UTC. To help cover for this outage, the GOES-13 (GOES-East) satellite was paced into Full Disk scan mode, which provided only 1 image every 30 minutes. During this time period, the 1-minute imagery from GOES-14 (shown below) was essential to monitor such features as a wildfire burning southeast of Ely, Nevada (station identifier KELY). Two apparent flare-ups of the fire were seen in the areal coverage of the hottest pixels (red) on GOES-14 Shortwave Infrared (3.9 µm) images at 1805 UTC and 1807 UTC, which were not captured by the 30-minute GOES-13 imagery. In fact, the 1745 UTC GOES-13 Shortwave Infrared image suggested that there was a brief reduction in the intensity of the fire (indicated by a lack of red pixels), which was not the case according to the 1-minute GOES-14 imagery.
The corresponding GOES-13 Water Vapor (6.5 µm) images (below) perhaps highlighted the transverse banding features a bit better at times, since the weighting function for that spectral band generally peaks in the middle to upper troposphere where the transverse banding cloud features existed.A sequence of Infrared Window images from POES AVHRR (10.8 µm) and Suomi NPP VIIRS (11.45 µm) (below) showed a higher-resolution view of the initial formation of transverse banding during the 0411 to 1008 UTC time period. Shown below are two other types of satellite imagery that can be helpful for identifying the areal extent of transverse banding cloud features: the Suomi NPP VIIRS Day/Night Band (0.7 µm), and the MODIS Cirrus band (1.37 µm). A similar Cirrus band will be part of the ABI instrument on GOES-R.