G16-CH13_10.3_IR-Clean

Monitoring the Remnants of Ian from GOES-16

Posted by Kevin Thiel (CIWRO) on 10/03/2022
Posted in: G16-CH07_3.9_SWIR, G16-CH13_10.3_IR-Clean, Nighttime Microphysics RGB, SPC. Leave a comment

On Saturday October 1st the remnants of Hurricane Ian were moving northward through the Mid-Atlantic region, after making a second U.S. landfall the previous day in South Carolina. Overnight, the SPC was monitoring the final stages of Ian’s extra-tropical transition with a marginal threat for severe weather in the coastal North Carolina/Virginia region.

One forecaster on shift that night was monitoring the remnants from the perspective of GOES-16, and noted how various ABI products could be used to examine cloud layers and types in this dynamic environment.

CH7 shortwave and CH13/15 longwave IR shows mainly the cooler cloud tops associated with high-level clouds. Low-level clouds can be inferred by the warmer temps (CH7) or weaker grey features in CH13/15. However, the NtM [Nighttime Microphysics] RGB composite satellite data neatly contrasts colder, high-level clouds (western PA westward and in a warm conveyer belt over the Atlantic) from the lower but cool clouds (North Carolina into Virginia) and the very low, warm clouds (southeast Pennsylvania into New Jersey and Delaware). Though buoyancy is scant and severe is not expected in this area, the NtM RGB composite’s ability to contrast cloud types in this event demonstrates potential to identify important cloud features related to severe weather.

SPC Forecaster Comment

When overlaid with the RAP mesoanalysis field at 500 mb, the Channel-13 (Clean Longwave IR) and Channel-7 (Shortwave IR) bands from the ABI reveal the higher, cooler cloud tops north of the low into Pennsylvania. The warm conveyor belt over the Atlantic coast can be seen in the 500 mb RAP mesoanalysis with enhanced southerly winds east of low, and from the ABI infrared imagery with a lack of high clouds due to upper level subsidence.

Channel 13 (clean longwave IR) imagery of Ian’s remnants from the perspective of GOES-16. Overlaid with 500 mb RAP mesoanalysis data.
Channel 7(shortwave IR) imagery of Ian’s remnants from the perspective of GOES-16. Overlaid with 500 mb RAP mesoanalysis data.

While these bands individually can be used to point out these features, the forecaster notes that the Nighttime Microphysics RGB allows them to more readily identify and monitor these cloud features from the tropical cyclone remnants at night. This is driven by the RGB’s ability to combine information from multiple ABI bands (7, 13, and 15) to provide qualitative information for forecasters regarding cloud types and heights.

Nighttime Microphysics RGB imagery of Ian’s remnants from the perspective of GOES-16. Overlaid with 500 mb RAP mesoanalysis data.

Kevin Thiel, OU CIWRO

Oklahoma Supercells at Sunset from GOES-16

Posted by Kevin Thiel (CIWRO) on 04/26/2022
Posted in: Day Cloud Phase Distinction RGB, G16-CH13_10.3_IR-Clean, GLM, RGB, SPC, Tornado. Leave a comment

Supercells were expected to initiate along a dryline in west-central Oklahoma during Saturday evening on April 23rd. The Storm Prediction Center had issued a slight risk of severe storms in their 1630 Z (1:30 PM CDT) outlook, with the risk tornadoes (5%), damaging hail (15%), and damaging wind (15%). Thunderstorms initiated around 2200 Z (5:00 PM CDT) as shown from the Day Cloud Phase Distinction RGB animation below. As the sun began to set near the end of the animation, decreasing contributions from the green (Channel 2, visible) and blue (Channel 5, near-IR) bands created a shift to more red colors in the imagery (Channel 13, clean-IR).

Animation of the Day Cloud Phase Distinction RGB from 2130 to 2300 Z (4:30-6:00 PM CDT).

An SPC Mesoscale Discussion and Tornado Watch, along with NWS Norman Public Information Graphics show the transition from the initial SPC Convective Outlook to the warnings that would later be issued that evening. (Images below in chronological order)

As convection matured into supercells after sundown, satellite imagery became confined to the infrared bands (Channels 7-16), with Clean-IR imagery most often used. Additionally, rapidly updating (1 minute) lightning data from the GLM Flash Extent Density product can provide information about thunderstorm trends between NEXRAD full-volume scans (4-5 minute updates). At night, the GOES-16 GLM detection efficiency often exceeds 90% across the south-central United States.

Intensification of two supercells and tightening of their low level mesocyclones, southwest of Oklahoma City and southwest of Stillwater, as indicated by radar prompted the NWS Norman office to issue tornado warnings for both storms. The Tornado Warning for the Stillwater supercell was issued at 2359 Z (6:59 PM CDT), and the Tornado Warning for the Oklahoma City supercell was issued at 0003 Z (7:03 PM CDT).

5-minute ABI and GLM data from 2330 to 0030 Z (6:30 – 7:30 PM CDT)
Left: GLM Flash Extent Density (5 minute total) overlaid on the ABI Clean-IR band.
Right: ABI Clean-IR Band.

The animation above is from 2330 Z to 0030 Z (5 minute intervals), and shows how both storms intensified from the perspective of the GLM FED and ABI Clean-IR products. Deep overshooting tops were observed from the ABI along with notable increases in GLM flash rates. In this scenario satellite information may have provided a ‘heads-up’ on which storms to monitor, along with additional confirmation of trends observed from NEXRAD.

One-minute data was observed from the GOES-East Mesoscale Domain for both products (below). In this scenario NWS Norman also had access to the Terminal Doppler Weather Radar at the Oklahoma City Airport (TOKC), providing 1-minute radar reflectivity and doppler velocity data within the vicinity of the airport. For the supercell near Oklahoma City, this may make a forecaster less reliant on one-minute satellite data when making warning decisions. However, for the storm southwest of Stillwater no TDWR data was available. The rapid increase in lightning flash rates identified by the GLM FED product for this storm can provide additional verification for an NWS forecaster that the updraft was intensifying, and tightening of the low level mesocyclone prior to tornadogenesis may be imminent.

1-minute data from the GOES-East ABI (Clean-IR) and GLM (FED) within the mesoscale domain. Imagery is from 2350 – 0010 Z (6:50-7:10 PM CDT) (Click animation to view at full size)

Kevin Thiel (OU CIWRO)

Thunderstorms Initiating Overnight in Kansas and Oklahoma

Posted by Kevin Thiel (CIWRO) on 04/13/2022
Posted in: G16-CH13_10.3_IR-Clean, Nighttime Microphysics RGB, RGB. Leave a comment

During the late evening hours on April 12th, 2022, convection initiated along a retreating dryline and advancing cold front in southern Nebraska and central Kansas. Initiation across the line can be observed from the Clean-IR band (Ch 13) from GOES-16 and the NEXRAD mosaic below. The near-uniform initiation of these thunderstorms along the dryline provided a unique example of how GOES imagery can be combined with radar data to monitor rapid thunderstorm development and dissipation.

Additionally, the initiation and subsequent outflow boundary along the leading edge of the front produced an undular bore, which traveled across central Oklahoma from 0600 Z to 1000 Z and initiated convection just after 1030 Z. Tracking the bore/front in this scenario could have been done by the Clean-IR band or radar (as seen below). However, the Nighttime Microphysics RGB can provide additional information not observed from a single ABI band or from radar.

Strong contributions from the Green band (Ch 13 – Ch 7) and moderate contributions from the Red band (Ch 15 – Ch 13) in the RGB recipe make the green-yellow clouds formed along the bore stand out from the magenta surface. Early signs of initiation along from the front can also be observed from strong contributions by both the Red and Green band, with low contributions from the Blue band (Ch 13), and the development of stratus clouds in central and eastern Oklahoma indicate an environment with greater low level moisture. In this scenario, the Nighttime Microphysics can provide an early ‘heads up’ that CI may be coming soon as the front moves into a more favorable environment for severe weather in southeast Oklahoma, southwest Arkansas, and northeast Texas. This coincides with the SPC Mesoscale Discussion issued just after 1200 Z.

Kevin Thiel (OU CIWRO)

Triple Threat(s) in the Atlantic

Posted by Michael Folmer on 09/09/2017
Posted in: ABI, Convection, G16-CH10_7.3_WV-Low-Level, G16-CH13_10.3_IR-Clean, Hurricanes, NHC, OPC, RGB, Tropics, Uncategorized. Tagged: , , , , , , , . Leave a comment

The tropical Atlantic has been putting on quite the show over the last couple of weeks of Hurricane Harvey (Category 4). . .I’m sure you heard of that one, followed by Irma (Category 5), Jose (Category 4), and Katia (Category 2).  Katia made landfall last night in Mexico and now we continue our focus on Irma and Jose.  Why is it so active?  A few reasons:  warm ocean (sea surface temperature and high ocean heat content), lack of a true El Nino Southern Oscillation (ENSO) signal, though it looks like a weak La Nina, little to no shear throughout much of the basin, a lack of dust from the Sahara, and a strong Azores high.  Oh yeah, on top of that, we have the Madden-Julian Oscillation (MJO) more or less stuck in favorable phases for the Atlantic (8, 1, 2, 3) and forecasts suggest that stays in place for a while.

ECMF_phase_51m_small

ECMWF MJO verification and forecast courtesy of the Climate Prediction Center (CPC).  Click here to open in a new window.

NCPE_BC_phase_21m_small

GEFS MJO verification and forecast courtesy of CPC.  Click here to open in a new window.

One product I noticed in use at the Ocean Prediction Center (OPC) on Friday, 09/08/17 was the GOES-16 Daytime Convection RGB, so I thought this would be a nice opportunity to show you all three current Atlantic systems with a comparison to the 10.3 µm “clean” channel.

G16_DayConvection_Irma_20170908

GOES-16 Daytime Convection RGB of Hurricane Irma valid 1100 UTC to 2300 UTC on 09/08/17. *Preliminary, Non-Operational Data* Click here to open in a new window.

Note the bright yellow coloring that highlights, new convection with smaller ice particles indicating strong overshooting tops in the outer rainbands, while the main central dense overcast (CDO) surrounding the eye also gets brighter.  This indicates that after the eyewall replacement cycle ended, the new eyewall started to contract and strengthen (winds at this time were 155 mph, but shortly after this strengthened to 160 mph.

G16_10p3_Irma_20170908

GOES-16 10.3 um “clean” infrared window channel similar to the previous animation of Hurricane Irma.  *Preliminary, Non-Operational Data* Click here to open in a new window.

Notice that the 10.3 µm “clean” window shows us the brightness temperature of the coldest cloud tops.  Although you can see the new overshooting tops, as those thunderstorms rotate around the CDO, it gets more difficult to identify the newer, important convection.

G16_DayConvection_Jose_20170908

GOES-16 Daytime Convection RGB for Hurricane Jose valid 1000 UTC to 2045 UTC on 09/08/17. *Preliminary, Non-Operational Data* Click here to open in a new window.

By contrast, notice how compact Hurricane Jose became as it strengthened to a 150 mph Category 4 hurricane on Friday (09/08/17).  Again, the beginning of the animation shows plenty of yellows that indicate new convection, wile the older convection fades to oranges, then reds.  Also notice how the CDO becomes more yellow as the eye becomes cleaner and the storm takes on a more donut structure, even with the strong outflow channel to the northeast that makes the storm look lopsided.  Could this RGB be helpful in identifying CDO changes?  Or help with indicating eyewall replacement cycles (ERCs) in conjunction with microwave imagery?

G16_10p3_Jose_20170908

GOES-16 10.3 um “clean” infrared imagery similar to the previous animation of Hurricane Jose. *Preliminary, Non-Operational Data* Click here to open in a new window.

Again, to contrast the Daytime Convection RGB, the above 10.3 µm animation shows very cold cloud tops, but the newer convection starts to blend in with the CDO over time.  Do you see other differences?

G16_DayConvection_Katia_20170908

GOES-16 Daytime Convection RGB of Hurricane Katia valid 1200 UTC to 2357 UTC on 09/08/17. *Preliminary, Non-Operational Data* Click here to open in a new window.

Finally, Hurricane Katia was very small in comparison with the other two hurricanes, but notice there are differences in the intensity of the convection on Friday (09/08/17).    What do you see in the imagery?  There are less yellows than in Irma or Jose, yet the storm intensified to a Category 2, 90 kt (105 mph) hurricane prior to landfall on Friday evening.  The warming clouds and less cold, newer convection may have been due to dry air entrainment due to the close proximity to mountainous land nearby and a weak trough to the north.

G16_10p3_Katia_20170908

GOES-16 10.3 um “clean” infrared imagery similar to the previous animation of Hurricane Katia. *Preliminary, Non-Operational Data* Click here to open in a new window.

How does the 10.3 µm imagery above contrast with the Daytime Convection RGB?

So, what is steering Irma?  What about Jose and Katia?  Well, I’m glad you asked. . .

20170909_0900_G16_AirMass_ATL

GOES-16 Air Mass RGB image valid at 0900 UTC 09/09/17. *Preliminary, Non-Operational Data* Click here to open in a new window.

The GOES-16 Air Mass RGB image (courtesy of NASA SPoRT) above with my crude drawings show a rough idea of the players affecting the steering flow around the three hurricanes.  Katia has made landfall as it was pushed southwest due to the old cold frontal boundary (responsible for the cool air in most of the country) along with a disturbance highlighted in the yellow circle.  This disturbance will close off over the Tennessee Valley area and help to pull Hurricane Irma north, then northwestward in the next 48 hours.  Finally, Jose (east of the Lesser Antilles) will be pulled north through a weakness in the ridge due a weakness created by the Tropical Upper Tropospheric Trough (TUTT in the yellow “T”) to the northeast and Irma’s broad circulation.  Since the current trough over the northeast U.S. moves east/northeast and the central Atlantic TUTT remains stationary, Irma gets left behind in the southeast U.S., but weakening after landfall, while Jose gets left behind and may perform a tight anticyclonic loop before “possibly” moving northwest.  We’ll deal with Jose later. . .

I have included the GOES-16 Air Mass RGB and 7.3 µm low-level water vapor animations below so you can get a better feel of the overall pattern.

G16_AirMass_ATL_20170908

GOES-16 Air Mass RGB animation valid 0800 UTC 09/08/17 to 0900 UTC 09/09/17. *Preliminary, Non-Operational Data* Click here to open in a new window.

G16_7p3_ATL_20170908

GOES-16 7.3 um low-level water vapor animation valid from 0800 UTC 09/08/17 to 0715 UTC 09/09/17. *Preliminary, Non-Operational Data* Click here to open in a new window.

My final thoughts. . .please follow the National Hurricane Center for official track and intensity guidance on Irma and Jose.  I have included the track forecasts below.

095407_5day_cone_no_line_and_wind

The 8 am EDT NHC track forecast for Hurricane Irma. Click here to open in a new window.

115856_5day_cone_no_line_and_wind

The 8 am AST NHC track forecast for Hurricane Jose. Click here to open in a new window.

Thanks for reading!