CIMSS Satellite Blog

Tropical Invest 90E becomes Tropical Storm Andres

May 8th, 2021 | Scott Bachmeier

GOES-17 “Red” Visible (0.64 µm) and "Clean" Infrared Window images [click to play animation | MP4]

GOES-17 “Red” Visible (0.64 µm) and “Clean” Infrared Window (10.35 µm) images [click to play animation | MP4]

1-minute Mesoscale Domain Sector GOES-17 (GOES-West) “Red” Visible (0.64 µm) images (above) showed the convective banding associated with Tropical Invest 90E in the East Pacific Ocean on 08 May 2021. Invest 90E was centered along a northward bulge in the ITCZ/Monsoon Trough (below).

GOES-17 “Clean” Infrared Window (10.35 µm) image (Mesoscale Sector), with an overlay of the 12 UTC surface analysis [click to enlarge]

Invest 90E was located over water characterized by modest Ocean Heat Content and very warm Sea Surface Temperature values (below), favorable factors for further intensification.

Ocean Heat Content and Sea Surface Temperature [click to enlarge]

===== 09 May Update =====

GOES-17 “Red” Visible (0.64 µm) and “Clean” Infrared Window (10.35 µm) images [click to play animation | MP4]

1-minute GOES-17 Infrared and Visible images on 09 May (above) showed the period where Invest 90E intensified to a Tropical Depression (at 0900 UTC) and then to Tropical Storm Andres at 1500 UTC — the earliest calendar year tropical storm on record in the East Pacific basin. The convective overshooting tops occasionally exhibited infrared brightness temperatures of -90ºC or colder (yellow pixels embedded within dark purple regions).

A GOES-17 Infrared / Water Vapor Difference product (reference) from the CIMSS Tropical Cyclones site (below) highlighted areas of deep convection where overshooting tops were likely penetrating the tropopause (yellow to red enhancement).

GOES-17 Infrared – Water Vapor Difference product [click to enlarge]

GOES-17 Infrared images, with an overlay of deep-layer wind shear (below) indicated that Andres was approaching an environment of moderate to high shear, which would limit intensification.

GOES-17 Infrared images, with an overlay of deep-layer wind shear [click to enlarge]

===== 10 May Update =====

GOES-17 “Red” Visible (0.64 µm) and “Clean” Infrared Window (10.35 µm) images [click to play animation | MP4]

On 10 May, 1-minute GOES-17 Infrared and Visible images (above) showed that after one final convective burst, the low-level center of Tropical Storm Andres became exposed — and the storm was then downgraded to a Tropical Depression at 2100 UTC.

Posted in GOES-17, Satellite winds, Tropical cyclones | No Comments »

Blowing dust across Mongolia and China

May 6th, 2021 | Scott Bachmeier

Himawari-8 Dust RGB images [click to play animation | MP4]

JMA Himawari-8 Dust RGB images (created using Geo2Grid) covering the 48-hour period from 21 UTC on 04 May to 21 UTC on 06 May 2021 (above) revealed multiple plumes of blowing dust (brighter shades magenta/pink) which originated over parts of Mongolia — and were then transported southeastward and eastward across northeastern China.

Surface analyses from the Korean Meteorological Agency (below) showed an impressive pressure gradient between a midlatidude cyclone (moving southeastward from Mongolia into China) and high pressure moving southward behind it. Some of the airborne dust was entrained into the circulation of this low pressure system.

Surface analyses during the period from 21 UTC on 0 May to 21 UTC on 06 May [click to enlarge | MP4]

Surface analyses during the period from 21 UTC on 04 May to 21 UTC on 06 May [click to enlarge | MP4]

VIIRS True Color RGB mages from Suomi NPP and NOAA-20 viewed using RealEarth (below) showed the hazy arc of blowing dust along the trailing cold front (south of the cyclone in northeastern China) on 6 May.

VIIRS True Color RGB mages from Suomi NPP and NOAA-20 [click to enlarge]

Posted in Air quality, Himawari-8, NOAA-20, RealEarth, Red-Green-Blue (RGB) images, Suomi NPP, VIIRS | No Comments »

Severe weather across much of the Southeast US

May 4th, 2021 | Scott Bachmeier

GOES-16 “Red” Visible (0.64 µm) images, with SPC Storm Reports plotted in red [click to play animation | MP4]

1-minute Mesoscale Domain Sector GOES-16 (GOES-East) “Red” Visible (0.64 µm) images (above) include time-matched plots of SPC Storm Reports (predominantly widespread damaging winds, with some large hail and a few tornadoes) produced by a large and long-lived Mesoscale Convective System (MCS) that moved eastward across much of Mississippi and Alabama on 04 May 2021. The strong winds — with some gusts in excess of 70 mph — caused power outages which affected several hundred thousand residents (and persisted into the next day: MS | AL).

The corresponding 1-minute GOES-16 “Clean” Infrared Window (10.35 µm) images (below) showed numerous overshooting tops that exhibited infrared brightness temperatures in the -75 to -70ºC range (white pixels embedded within black areas). The MCS also produced heavy rainfall and flooding in parts of northern Alabama.

GOES-16 “Clean” Infrared Window (10.35 µm) images, with SPC Storm Reports plotted in cyan [click to play animation | MP4]

? It rained a little yesterday…

Rainfall totals of 5-7″ (locally higher) fell across parts of the Birmingham metro & much of Shelby Counties. This lead to significant flooding in many areas. Thankfully, there were no fatalities. #alwx pic.twitter.com/ko0TmYhNUo

— NWS Birmingham (@NWSBirmingham) May 5, 2021

Larger-scale views of 5-minute CONUS Sector GOES-16 Visible and Infrared images are shown below. Several additional MCSs produced a variety of severe weather across other parts of the Southeast US.

GOES-16 “Red” Visible (0.64 µm) images, with SPC Storm Reports plotted in red [click to play animation | MP4]

GOES-16 “Clean” Infrared Window (10.35 µm) images, with SPC Storm Reports plotted in cyan [click to play animation | MP4]

Posted in GOES-16, Heavy rain / flooding, Severe convection | No Comments »

ProbSevere products over the Southern Plains

May 3rd, 2021 | John Cintineo

The NOAA/CIMSS ProbSevere portfolio contains AI models for nowcasting convective weather. I’ll use Monday’s severe weather over the Southern Plains to highlight several of them.

A strong cold front spawned numerous severe-hail, wind, and tornado producing storms over Texas and Oklahoma, aided by very large values of convective available potential energy (CAPE; > 4000 J/kg). You can see numerous storm reports in Figure 1.

Storm Prediction Center’s preliminary severe storm reports for May 3rd, 2021.

Probsevere version 2 (PSv2) is an operational set of models at NOAA, which predict the probability of severe hail, severe wind, and tornadoes, in the next 60 minutes. The models are storm-centric, and the models’ domain is the entire contiguous United States (CONUS). These models use MRMS (radar), GOES (satellite), short-term NWP, and terrestrial-based lightning observations to generate probabilistic guidance of severe hazards. Figure 2 shows output from an experimental version (PSv3), which includes additional MRMS, GOES, and NWP fields as predictors in a machine learning model.

Figure 2: ProbSevere v3 contours (colored, around storms), MRMS MergedReflectivity, and NWS severe weather warnings (yellow and red boxes) for storms over the Southern Plains. The second outer contour around some storms is colored by the probability of tornado.

Another ProbSevere product is a convolutional neural network that uses GOES-R ABI and GLM images to detect regions of intense convection, and is often correlated with strong overshooting tops, “bubbly-like” texture in visible imagery, strong lightning cores, and the cold-U/above-anvil cirrus plume signature. The intense convection probability (ICP) can be run on the 1-minute mesoscale scans as well as 5-minute CONUS sector scans aboard the GOES satellites. The ICP does not require radar data, and may also be able to operate on data from satellites with similar intruments (e.g., Meteosat Third Generation). ICP output is being used as a predictor in the experimental ProbSevere v3.

Predicting when and where lightning will occur is also important for many users, such as mariners, aviators, and outdoor event managers. The probability of lightning model (PLTG) is also a convolutional neural network, using images of visible, near-infrared, and longwave-infrared channels to nowcast lightning occurrence in the next 60 minutes. The purple-to-orange shaded regions in the video below show GLM flash-extent density (i.e., flashes passing through a location).