High spatial resolution satellites like the Landsat series operated by NASA and the US Geological Survey, or Sentinel operated by the European Space Agency, are often used for land process investigations. Their very high spatial resolution comes at the cost of less frequent overpasses over specific locations, and so they aren’t used as regularly for meteorological purposes as the coarser-but-more-frequent observations from low-earth orbiting instruments like VIIRS or the multiple observations per hour that geostationary satellites produce. However, phenomena of interest to meteorologists can still be found in these satellites if they happen to fly over at the right time.

A month’s worth of observations from the Sentinel-2 satellite shows this very well. Depending on the channel, spatial resolution from Sentinel-2 can be as fine as 10 m which results in very highly detailed imagery of Earth’s surface and the clouds above it, but together the two Sentinel-2 satellites only pass over a location once every five days. Here, several images from the month of January 2025 are shown depicting Chicago and the southern tip of Lake Michigan. Early on in the month, the lake was ice-free as the water temperatures remained well above freezing. By mid-month, however, temperatures plunged into the single digits Fahrenheit overnight and ice began to form in the shallower regions near the lakeshore (for example, see this 15 January blog post).

Consistent offshore winds helped push newly-formed ice into the middle of the lake. At times, these winds can be measured from space using the Advanced Scatterometer (ASCAT) instrument deployed aboard EUMETSAT’s Metop series of polar orbiting satellites which derives wind speed and direction from the radar reflective properties of surface water waves. The Great Lakes are large enough that useful wind measurements can be obtained from them via satellite. For example, ASCAT winds from 20 January show strong westerly flow from the land and over the lake.

As the wind pushed newly-formed ice away from the shore, new ice could form in the same shallow regions. The very low temperatures in mid-to-late January(the high temperature in Chicago was only 2 F on 21 January) caused a significant amount of western Lake Michigan to freeze.

The Sentinel overflights also uncovered some very interesting industrial impacts on cloud formation. The below image is from 24 January 2024. Very faint plumes are visible in the true-color imagery stretching to the northeast, originating from downtown Chicago and the steel mills and oil refineries of northwest Indiana. These plumes track across Lake Michigan where they serve as cloud nucleation that enhances the development of the elevated convection seen off of the western edge of the state of Michigan. In essence, the output of these significant areas of heavy industry is seeding clouds that form dozens of kilometers downwind. The very-small scale of these plumes means they are difficult to identify when using almost any other satellite system.

A zoomed-out view, showing the size and scope of these enhanced cloud regions, comes from the more coarsely-resolved Sentinel-3 Ocean and Land Color Instrument (OLCI). In this case, it appears there is additional seeding from industry in southwestern Wisconsin.

While these instruments that are focused on land studies won’t have applications for every day in operational meteorology, these examples show that they are still useful for gaining a larger-picture view of the environment and uncovering interesting processes occurring at scales that might be too small to otherwise be detected.

Imagery source: Copernicus Browser, https://browser.dataspace.copernicus.eu/

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The potent cyclone (surface analysis, an airmass RGB animation from the College of Dupage website is below) that caused severe weather over Hawaii (blog post) is also drenching the islands with considerable rains. The animation of MIMIC Total Precipitable Water, above, shows the storm drawing tropical moisture northward from the Intertropical Convergence Zone. The airmass RGB, below, also shows that connection to the tropics, with the green area in the RGB that is moving northward over Hawaii.

How have various estimates of precipitation quantified the rains that have fallen? Hourly CMORPH-2 Rain Estimates captured at this RealEarth site (enter ‘CMORPH’ into the Search box; this website has data through 31 December 2024), below, capture the progress of the heavy rain band across the islands, mostly west to east, but with a couple of seemingly backward steps.

In contrast, GOES-18 GREMLIN estimates of MRMS radar reflectivity, shown below with GOES-18 mid-level water vapor infrared imagery, shows steady eastward progress to the heavy rainband. A band of lighter precipitation persists over Kauai however. The animation below suggests the backward steps in the CMORPH hourly precipitation shown above are artifacts that bear investigation. A discussion on how GREMLIN rain estimates are used over Pago Pago in the south Pacific is available here.

There is a direct broadcast antenna at Honolulu Community College (link) and microwave data from that site can be used to derive instantaneous rain rates (via MIRS algorithms). The animation below shows three snapshots between 0715 and 1215 UTC.

How do the instantaneous rain rates compare with GREMLIN MRMS estimates? Three comparisons are shown below. The figures are qualitatively similar.

When evaluating heavy rains, there are many products available to a forecaster. Use them all to increase confidence in the diagnostics.

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With the increasing threat for strong to severe convection across the western portion of Hawai’i, a Severe Thunderstorm Watch was issued for an area centered on the island of Kauai at 1522 UTC on 30th January 2025 (above).

5-minute CONUS Sector GOES-18 Clean Infrared Window (10.3 µm) images (above) showed elongated clusters of convection moving eastward and northeastward across Kauai and Oahu — with embedded thunderstorms that produced heavy rain and strong winds on those two islands (Local Storm Reports).

A corresponding animation of GOES-18 Infrared images with an overlay of GLM Flash Extent Density (below) displayed the abundant lightning activity associated with these thunderstorms.

This convection was occurring within the warm sector of a deepening Gale Force to Storm Force low pressure system (bottom left on these surface analyses) that was located NW of the island chain — and the strong SW flow in advance of this storm system (and its cold front) interacting with island terrain produced wind gusts as high as 120 mph on Maui at 0850 UTC.

The air mass within the warm sector was also unusually moist — in fact, a new daily record rainfall of 3.57 inches occurred at Honolulu. The Total Precipitable Water (PW) value of 1.98″ derived from Lihue, Kauai rawinsonde data at 1200 UTC on 30th January was a record high value for that date/time, according to the SPC Sounding Climatology site (below).

The PW value derived from Lihue rawinsonde data at 1800 UTC on 30th January (about 2.5 hours after the Severe Thunderstorm Watch was issued) was even higher, at 2.06″ (below).

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Geo2grid software accesses SatPy libraries that allow for the reading of level-1c netcdf files holding FCI (Flexible Combined Imager) data from the latest operational Meteosat satellite (Meteosat-12). So if you can access to that output, you can create beautiful images as the ones shown above. The RGB shows a storm moving into western Europe. The Red/Orange in the image is associated with the Potential Vorticity Anomaly helping to support the storm (a second Potential Vorticity Anomaly is apparent over the central Mediterranean, and there seems to be one over the Arabian Peninsula too — maybe that’s a Westerly Disturbance for India later this weekend) To create the image above, I first moved all 40 (!) image sectors holding the data valid at 0000 UTC on 30 January 2025 to my computer that holds the geo2grid software (downloadable from this link). The geo2grid documentation includes a section on readers, including the FCI Level-1c reader.

The two geo2grid commands to create the image above are shown below. One creates the .tif file, one adds coastlines to the image. In geo2grid call, those last 4 wildcards (????) refer to the 40 different sectors (that is, 0001, 0002, 0003, 0004, … , 0039, 0040) that hold the data. The 0001 in the filename refers to the 1st image of the day.

./geo2grid.sh -r fci_l1c_nc -w geotiff -p airmass -f /pathtoL1CData/W*FDHSI*_0001_????.nc
./add_coastlines.sh --add-coastlines --coastlines-resolution f MTG-I1_FCI_airmass_20250130_000000_mtg_fci_fdss_2km.tif 

As with other geo2grid commands, one can create a region into which you can subsect the data so you can focus on a particular region. This was done below to focus on parts of Europe.

/p2g_grid_helper.sh Europe4 10.0 45.0 4000 -4000 1440 1120 > Europe4.yaml
./geo2grid.sh -r fci_l1c_nc -w geotiff -p airmass -g Europe4 --grid-configs ./Europe4.yaml -f /pathtoL1CData/W*FDHSI*_0001_????.nc 
 ./add_coastlines.sh --add-coastlines --coastlines-resolution f MTG-I1_FCI_airmass_20250130_000000_Europe4.tif 

The output from that series of calls is shown below.

Thanks to EUMETSAT for sharing the data that allowed the creation of these beautiful images!

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