Tag Archives: USA

A gustnado near St. Louis

Gustnado_EileenLenkman_EasternMissouri_7May2016

Eileen Lenkman, 7 May 2016, eastern Missouri looking across Mississippi River toward Illinois

On May 7, 2016, a line of storms moved through the midwest. Eileen Lenkman shared a series of photos from eastern Missouri as the storms moved from the NW toward the SE.

In this first photo, the storm can be seen approaching the area.

Cumulonimbus1_EileenLenkman_EasternMissouri_7May2016

Eileen Lenkman, 7 May 2016, eastern Missouri looking toward Illinois

 

Composite radar imagery at this time shows the extent of this precipitating system as it moves toward the St. Louis area.

NCDCreflectivity_7May2016_Missouri_Squall

 

In the next photo, the heavily raining portion of the storm appears in Eileen’s view.

Cumulonimbus_EileenLenkman_EasternMissouri_7May2016

Eileen Lenkman, 7 May 2016, eastern Missouri looking toward Illinois

 

The rain locally cools the air, which spreads out near the ground away from the raining core of the storm. The leading edge of this rain-cooled air is referred to as a gust front and is typically accompanied by strong winds.

gustfront

Schematic showing the gust front at edge of rain-cooled air

Not only is there a marked temperature distance across the gust front between the rain-cooled air behind it and the warm, moist air ahead, difference in wind speed and direction behind and ahead of the gust front can create considerable horizontal wind shear across that boundary far out ahead of the raining core of the storm. The warm, moist air is lifted up and over the colder dense air behind the gust front. This upward motion can tilt and vertically stretch the small-scale vortices that can form along the edge of the gust front due to the horizontal wind shear, creating a spinning vortex that can extend upward from the ground; this is casually referred to as a “gustnado.

gustnado_COMET

This shallow, short-lived vortex may only extend upward 10s of feet above the ground with no apparent connection to the cloud above. Away from the raining core, a debris cloud or dust whirl is seen near the surface. Wind speeds can reach 60-80 mph in these gustnadoes, but they are not considered to be a tornado as they are not associated with any sort of parent rotation in the cloud above.

On 7 May 2016, when the storms were moving near St. Louis, Eileen Lenkman captured one of these gustnadoes on camera.

Gustnado_EileenLenkman_EasternMissouri_7May2016_annotated

Gustnado, Eileen Lenkman, 7 May 2016, eastern Missouri looking toward Illinois

In this photo, the raining core can be seen to the far left of the photo while out to the right the small debris whirl near the surface can be seen at presumably the leading edge of the gust front.

 

Views of the April 26 severe storms from above and below

“Well that looks ominous” said Meredith O’Neill Muminovic as she took this photo of an approaching storm on 26 April 2016 in St. Louis, Missouri. The shelf-like appearance of the storm’s leading edge indicates strong winds as rain-cooled air lifts warmer, moist air out ahead of it. At the time of this photo, a Severe Thunderstorm Warning was in effect as 60+ mph winds were reported in the area, as well as hail 1″ in diameter covering the ground in some locations.

Shelf Cloud, Meredith O'Neill Muminovic, St. Louis, Missouri 26 Apr 2016

Shelf Cloud, Meredith O’Neill Muminovic, St. Louis, Missouri 26 Apr 2016

 

The corresponding radar image from around this time shows that the storm Meredith photographed was part of a line of storms moving across Missouri, referred to as a squall line. The red and orange areas in radar reflectivity indicate the heaviest rain, with weaker but widespread rainfall following behind the leading edge. The yellow box around St. Louis indicates the area under the Severe Thunderstorm Warning, which is aligned where the squall line appears bowed.

Radar Reflectivity, St. Louis, Missouri, 26 Apr 2016 2:07 PM CDT

Radar Reflectivity, St. Louis, Missouri, 26 Apr 2016 2:07 PM CDT

 

The bow echo is commonly associated with strong, often damaging winds at the surface. Much research has gone into studying bow echoes, leading us to understand how they form and the resulting weather they cause. The bow structure is strongly related to the wind shear of the environment these storms form in, meaning how the winds change direction and speed with height.

bowecho_meted

Underneath the storm, turbulent motions are also present, as nicely captured by this video by Billy Reed in St. Louis around the time of Meredith’s photo.

 

Above, the clouds are deep and, individually, take on the classic structure of a cumulonimbus. In this schematic from the National Weather Service’s online school, JetStream, you can see that where the radar reflectivity shows the heaviest rain with the reds and oranges, the cloud is deep. Warm, moist air flows into the storm from out ahead of the squall line, fueling the strong updraft which hits a stable layer aloft, usually the tropopause, and creating an overshooting top. Within those strong updrafts, large hail can grow as supercooled liquid water freezes upon ice. Smaller Ice crystals can be carried outward to form the anvil of the cumulonimbus or fall and melt behind the updraft, contributing to the heavy rainfall at the surface and lighter rain extending behind the main leading line.

Schematic showing a vertical cross section of the cloud, precipitation, and air motion associated with the radar image of a squall line (from NWS)

Schematic showing a vertical cross section of the cloud, precipitation, and air motion associated with the radar image of a squall line (from National Weather Service)

 

The rain cools the air near the surface relative to the surrounding environment. This rain-cooled air rapidly moves outward away from the rainy core. The leading edge of this dense, cool air is referred to as a gust front.

Labeled schematic of a squall line storm from University of Illinois Urbana-Champaign

Labeled schematic of a squall line storm from University of Illinois Urbana-Champaign

 

Warm, moist air that’s flowing in towards the storm is lifted up and over this denser, colder air along the gust front, leading to new cloud formation, and sometimes the shelf cloud that extends outward from the main line of storms, as was shown in Meredith’s picture above.

This multi-cell nature that allows these storms to persist can be seen in this photo from  western Oklahoma on this day, when Jack Christian also had his eyes to the sky. The anvil of this series of this multicellular storm over northern Texas extended far across the Plains, with newer cumulus congestus clouds forming in its vicinity. Notice the tilt in these cumulus congestus clouds, as the strong wind shear indicates increasing winds with height, but turning in direction from the tops of these clouds to the top of the cumulonimbus as the anvil spreads out in the other direction.

Cumulonimbus, Multicell, Jack Christian, Elk City, Oklahoma, 26 Apr 2016 5 PM CDT

Cumulonimbus, Multicell, Jack Christian, Elk City, Oklahoma, 26 Apr 2016 5 PM CDT

 

So we’ve taken a good look at these storms from below, but what about above? Matt Barto was flying over Oklahoma later that afternoon and was treated to this spectacular view of the storms from above. Look at the classic structure of this cumulonimbus, with the anvil spreading outward from the bubbling core.

Cumulonimbus, Matt Barto, over Oklahoma 26 Apr 2016

Cumulonimbus, Matt Barto, over Oklahoma 26 Apr 2016

 

We live in the era where 1-min visible satellite data is available and it’s incredibly valuable for looking at the evolution of these storms. Here’s a 30-min loop showing the storms over Oklahoma and Texas where you can see the bubbling nature of the individual clouds, with the overshooting tops clearly visible, the anvils spreading outward, and gravity waves resulting from the displacement of mass in the atmosphere by these massive storms.

GOES 14, 1-min Visible Sector 26 April 2016 2220- 2250 UTC

GOES 14, 1-min Visible Sector 26 April 2016 2220- 2250 UTC

 

At the end of the day, not only where there very strong wind reports (blue dots) from the squall lines, but over 30 reports of tornadoes (red) and hundreds of reports of hail (green) including some baseball-sized.

26 April 2016 Severe Reports

26 April 2016 Severe Reports

 

Did you experience severe weather this day? We’d like to hear your story and see your cloud photos.