Long-time residents of the Great Lakes region know the significant impact that the lakes can have on the local weather. One of the most familiar effects is the lake breeze. Because it takes a long time for the lakes to warm up after winter while the land heats up comparatively quickly, during the spring and early summer the lakes are much cooler than the surrounding land. This creates a density gradient which forces a baroclinic circulation, resulting in a cool breeze blowing from the lake to the land.

However, in the fall the opposite can happen. Just as it takes the lakes a long time to warm up in the spring, it takes a long time for them to cool down in the fall. At the same time, the land cools off quickly, especially at night.  This creates a similar gradient as the springtime lake breeze, but this time the gradient is reversed. As a result, an offshore flow of cool air flows toward the lake.

An example of this can be seen in the GOES-19 satellite imagery over Lake Michigan on the morning of October 30 2025. Overnight, the outer edges of a midlatitude cyclone centered over the southeast continental United States pushed moisture and cloudiness westward across Lake Michigan. Earlier in the evening, the eastward motion was able to propagate unabated cross the lake and into Wisconsin. However, as the night grew longer, the land breeze developed and served as a counterbalancing force, creating an edge to the cloudiness that persisted until sunrise.

The following animation shows this process in detail. It begins at 2130 UTC (3:30 PM local time) on the 29th and depicts both the GOES-19 Band 13 (10.3 micron) brightness temperature and the surface weather observations. Given the fact that this event transitions from day to night and back to day again, looking at a single-channel infrared loop allows us to use the same product for the entire period. A visible product is not usable at night, and many RGB products rely on shortwave channels and thus cannot be easily interpreted for both day and night scenes.

Note that at the beginning of the loop, the air temperature recorded by the buoy in the middle of the lake is not that different from the air temperatures from sites in western Wisconsin. At 0230 UTC (9:30 PM local time) the central lake buoy records an air temperature of 54 F with a northeasterly wind. Racine, Wisconsin, shows an air temperature of 52 F at the same time, with the same northeasterly wind. However, as the sun sets, the temperature difference grows as the night continues. By 0530 UTC (12:30 AM local time) the situation has significantly changed. The buoy is in a location with very little nocturnal cooling: it has drooped one degree to 51 F. However, Racine has cooled substantially and is now reporting a temperature of 45 F. Furthermore, the buoy wind is still northeasterly while the wind at Racine is now northwesterly. This flip in the wind direction indicates that the land breeze has formed.

At 10 UTC the temperature gradient has gotten even stronger: 50 F for the lake air and 40 F for the terrestrial air, and by 1100 UTC (6:00 AM local time) the lake breeze is visible on the satellite as an edge to the cloudiness over the lake running roughly parallel to the lake’s western shore. Cloud were forming over the lake as the relatively warm and moist lake surface was able to create convection in the cooler air lying higher up. However, the advancing land breeze stabilized the air and inhibited convection where it advanced. This boundary is clearly visible on the night microphysics RGB. (Note also the large regions of fog throughout many parts of Wisconsin. These are identifiable as the areas of light green. The valley fogs forming in the river valleys of western Wisconsin are particularly notable).

As the sun rises, however, the temperature gradient breaks down. The land near the shore is able to heat up much more quickly than the lake is. By 1400 UTC (9:00 AM local time) the lake is only 6 degrees warmer than the land stations. The larger-scale synoptic winds are able to overcome the land breeze and push the clouds ashore. This animation from CSPP Geosphere shows the night to day transition.

Note that the land breeze front is better maintained in the northern part of the lake. There are a couple of reasons for this. First, it is colder up there. Overnight, terrestrial air temperatures dropped to the mid 30s F while the lake air temperatures remained around 50 F. Second, the presence of fog near shore means that less solar energy is available to change the temperature of the land due to reflection and latent heating. Thus, the gradient persists longer and the lake breeze is still able to inhibit convection over the western part of Lake Michigan.

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1-minute Mesoscale Domain Sector GOES-19 (GOES-East) Visible and Infrared images (above) showed Category 5 Hurricane Melissa as it made landfall along the far southwest coast of Jamaica around 1700 UTC on 28 October 2025. Low-altitude mesovortices were evident within the eye — and GLM Flash Points revealed abundant lightning activity within the inner eyewall region.

1-minute GOES-19 Infrared images displayed using RealEarth (below) indicated that the center of the eye of Melissa passed over White House, Jamaica during landfall — with the right-front quadrant of the inner eyewall (where wind damage and storm surge is often highest) passing over Black River.

Shortly after Melissa made landfall, the eye quickly became cloud-filled as the hurricane moved inland and interacted with topography across the western part of Jamaica (below).

A larger-scale view of GOES-19 CIMSS True Color RGB images created using Geo2Grid (below) indicated that after landfall, the eye of Melissa remained cloud-filled as the hurricane finished crossing the island and eventually emerged over water north of Jamaica around 2100 UTC. 

A larger-scale view of 1-minute GOES-19 Infrared images during the 5 hours leading up to landfall is shown below — which revealed a continual series of cloud-top gravity waves propagating radially outward from the eye of Melissa. The radius of hurricane-force winds appeared to be rather small, since surface wind speeds at the Kingston METAR site in eastern Jamaica were only in the 20-40 kt range during that time period.

A GMI Microwave image (below) displayed the compact eye and eyewall of Melissa about 3 hours prior to landfall.

Just prior to landfall, Melissa was moving through an environment characterized by fairly low values of deep-layer wind shear (below).

A Synthetic Aperture Radar (SAR) image (source) at 1110 UTC (below) retrieved a maximum wind velocity value of 143 kts in the NW quadrant of Melissa.

It is noteworthy that the Advanced Dvorak Technique (ADT) satellite-derived intensity estimate peaked at 185 kts for Melissa (below) — which according to the developer at CIMSS is the highest value on record for any tropical cyclone since the ADT was implemented.

219-kt peak wind would be the highest wind value a dropsonde has ever recorded, ahead of 215-kt value in Super Typhoon Megi in 2010 & the 210 kt recorded just yesterday in #Hurricane #Melissa.Still needs to be validated… so this data is preliminary.

— Philippe Papin (@pppapin.bsky.social) 2025-10-28T15:48:47.358Z

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1-minute Mesoscale Domain Sector GOES-19 (GOES-East) Infrared images (above) showed Tropical Storm Melissa in the Caribbean Sea as it began to rapidly intensify during the afternoon and evening hours on 25 October 2025 — reaching Category 1 intensity at 1800 UTC on 25 October and Category 3 intensity at 0300 UTC on 26 October. A series of convective bursts (exhibiting cloud-top infrared brightness temperatures as cold as -90 to -96C, denoted by darker shades of purple) rotated around the storm center — and GLM Flash Points highlighted intermittent lightning activity within some of those convective bursts. Some semblance of a ragged eye occasionally appeared as Melissa neared and attained Category 3 intensity, but an eye was never well organized in the infrared imagery.

Melissa then reached Category 4 intensity south of Jamaica at 1200 UTC on 26 October — and by that time the eye was well defined in both Infrared and Visible imagery (below). Low-altitude mesovortices were apparent within the eye in the Visible images.

The eye of Category 4 Melissa was exhibiting a “stadium effect”, with a small surface eye having walls that sloped outward with height (below).

Melissa was moving through an environment of relatively light deep-layer wind shear, and was traversing warm water — two factors that favored intensification (below).

===== 27 October Update =====

Post-sunrise 1-minute GOES-19 Visible and Infrared images on 27 October (above) again showed a nice “stadium effect” with the eye of Melissa, which reached Category 5 intensity south of Jamaica at 0900 UTC. Visible images continued to display low-altitude mesovortices within the 10-mile diameter eye — and GLM Flash Points highlighted abundant lightning activity within the inner eyewall.

The maximum sustained wind speed of Melissa was increased to 150 kts at 2100 UTC (SATCON | ADT).

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5-minute PACUS Sector GOES-18 (GOES-West) Mid-level Water Vapor and Upper-level Water Vapor images (above) displayed orographic waves downwind (southwest) of the Hawaiian Islands on 23 October 2025. With a ridge of high pressure north of Hawai’i (surface analyses), boundary layer flow from the northeast interacted with the topography of the island chain — generating vertically-propagating waves that were apparent in Mid-level (and to a lesser extent, even Upper-level) Water Vapor imagery (below).

Northwest of the Big Island of Hawai’i, there was one Pilot Report of continuous light turbulence between the altitudes of 18000-20000 ft (below).

One item of interest was the diurnal change in thermal signatures of the Mauna Kea and Mauna Loa summits — transitioning from cooler (darker shades of blue) during the nighttime at 1201 UTC to warmer (brighter shades of yellow) during the daytime at 0001 UTC (below).

Plots of Weighting Functions for the GOES-18 Mid-level and Upper-level Water Vapor spectral bands — derived using rawinsonde data from Hilo (PHTO) — showed the profiles of Band 08 and Band 09 weighting functions at 1200 UTC on 23 October to 0000 UTC on 24 October (below). The summits of Mauna Kea and Mauna Loa extend upward to near the 600 hPa pressure level — close to the level of strong weighting function contributions for Water Vapor spectral band 09 at each of those 2 times.

This diurnal variability of Mauna Kea and Mauna Loa thermal signatures in Water Vapor imagery has been discussed in previous blog posts here, here and here.

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