The 4 March 2020 FDTD Satellite Applications Webinar was a tag-team discussion of a high profile snow squall event in PA/NY led by Dave Radell (SOO at New York City, NY) and Mike Jurewicz (SOO at State College, PA). In this webinar Mike and Dave shared several tips and tricks for fellow forecasters who may face this type of phenomenon in their own offices in the future. Here is one example of how satellite data was used to give a more complete picture as the event unfolded:
“A product that’s gaining a lot of popularity is the Day Cloud Phase, it’s an RGB product […] I would highly recommend the RGB product not only for these snow squall scenarios but for convection in general. […] although you get some idea in the traditional visible of the cloud enhancements, it really jumps out at you on the RGB loop. As these cloud features are growing taller and you’re getting more glaciation at the higher levels. With the ingredients that go into the RGB loop you can see that red and orange tint so it really jumps out at you nicely what the developing convective features are versus the lighter blue shading which is the flatter more laminar stratocumulus features. Again it could be another clue as to what really are the features of interest.”
“These snow squalls can be pretty robust convection in the winter time but in the grand scheme they’re fairly shallow features so you’re going to have issues with radar overshooting. But if you can combine your radar analysis with satellite you can get a more complete picture of how things are evolving.”
FDTD Satellite Applications Webinars are peer-to-peer learning; staff from WFOs, National Centers, CWSUs, RFCs lead the presentations. The presentations are short (less than 30 minutes) and recorded for on-demand viewing.
A rapidly intensifying low pressure system made its way into the Atlantic on Tuesday, 11 February 2020 and quickly grew into a powerful extratropical cyclone producing hurricane force winds by Thursday, 13 February 2020. By 0600 UTC on 14 February 2020, the low bottomed out with a minimum low pressure of 929mb. This system deepened by more than 40 mb in 24 hours during its rapid intensification phase, classifying it as a “bomb” cyclone. It tracked north towards Iceland where it caused hurricane force wind gusts, the highest gust, although terrain enhanced, reached 159 mph (https://www.severe-weather.eu/recent-events/near-record-wind-gusts-255kmh-hafnarfjall-iceland-mk/). These gusts were recorded on the leading edge of the cyclone where the cold conveyor belt north of the occluded front in the N-NE quadrants played a role.
This intense extratropical cyclone was closely followed by another cyclone (named Dennis by the UKMet office) rapidly intensified during the day on 14 February 2020 deepening by 40 mb in 24 hours, classifying it as another bomb cyclone. This system is following a similar path as the previous cyclone, capitalizing on the favorable baroclinic environment left in the wake of the first cyclone.
GOES-E (16) Air Mass RGB animation of two powerful low pressure systems from 13 February to 15 February 2020. Click here for larger image.
In the RGB Airmass imagery (above) from GOES-16, it is clear that there is also a large potential vorticity anomaly (red shading) upstream of the system, originating from a trough over the eastern United States. This inflow of potential vorticity into the storm is aiding the rapid intensification of the system. This system deepened to 920 mb as of the Ocean Prediction Center (OPC) 1800 UTC analysis on 15 February 2020. Hurricane force winds have been sampled by ASCAT scatterometers and by aircraft in the early morning hours of 15 February 2020 with maximum winds of 94 kt!
ASCAT A, B, and C overlaid on MSG-11 10.8 um infrared imagery valid ~1700 UTC on 15 February, 2020 (Courtesy of James Kells (OPC)). Click here for larger image.
Altimeter passes overlaid on MSG-11 10.8 um infrared imagery valid ~1745 UTC on 15 February 2020 (Courtesy of James Kells (OPC)). Click here for larger image.
The above ASCAT and Altimeter images from ~1700-1745 UTC on 15 February 2020 show winds in the primary 920 mb low (south of Iceland) still at hurricane-force (>65 kt) with significant wave heights near 42 ft in the southeast quadrant. Meanwhile the older, lee-side low that was part of the 13 February 2020 storm is still exhibiting winds of 50-60 kt, aided by a barrier jet in eastern Greenland and a tip jet near the southern tip of Greenland. The altimeter readings near this latter storm were 30-42 ft (note that it’s possible higher waves (~50+ ft) were in the vicinity of both storms at this time).
ASCAT A, B, and C overlaid on MSG-11 10.8 um infrared imagery valid ~0000 UTC on 16 February 2020 (Courtesy of James Kells (OPC)). Click here for larger image.
Altimeter passes overlaid on MSG-11 10.8 um infrared imagery valid ~2015 UTC on 15 February 2020 (Courtesy of James Kells (OPC)). Click here for larger image.
These latest ASCAT and Altimeter passes show the 922 mb low (as of the 0000 UTC 16 February 2020 OPC analysis) has started to fill (weaken slightly) with plenty of storm-force wind barbs and significant waves still over 40+ ft, though higher winds of 65+ kt and waves over 50 ft are most likely not sampled.
We will have a more detailed recap of this past week’s stormy north Atlantic in the coming days, so please stay tuned.
On February 12, 2020, a very strong arctic cold front swept through the upper tier of the central CONUS bringing blizzard conditions, dangerous wind chills colder than -50 F, wind gusts exceeding 60 mph, and crashing temperatures to portions of the Dakotas, Minnesota, Iowa, and Nebraska. Despite little snowfall expected with this front (generally between 1-2 inches), blowing snow and significant visibility reductions appeared likely should the existing snow pack be susceptible to being lofted and blown around. But prior to this impactful frontal passage, forecasters were left with a difficult decision: just how susceptible is the existing snow pack to become lofted into blowing snow?
Figure 1: 11 Feb 2020 GOES-East Band 5 (1.61 um). Adjusted color scale to enhance ice sensing characteristics. Grey scale – Min: 3; Max: 30. Full res
One tool that could help forecasters answer this question is close examination of snow pack appearance on the 1.61 um Snow/Ice band offered on GOES-R ABI. It’s has been shown that the Snow/Ice band is sensitive to the amount of liquid water in a volume of snow and ice, i.e. its “water to ice crystal ratio” (CIMSS Blog example). We can apply this in operations by looking for “old, crusted over snow” from “new, fresh and fluffy snow.” In Figure 1, a swath of newly felled snowfall across eastern SD, southern MN, northern IA, into WI and MI can be seen as a lighter shade of grey compared to darker northern neighbors (you need to wait for bright white clouds to pull away to reveal the dark snow pack below). This lighter shaded area is where forecasters can more confidently delineate a fresher snow pack that may be more susceptible to being lofted and blown around. Lastly, this loop applies adjustment to the display range of the Snow/Ice band in order to more easily draw out this area, changing from the AWIPS default Min-Max of 0-100 to an adjusted Min-Max of 3-30.
Figure 2: 12 Feb 2020 GOES-East Nighttime Microphysics RGB. Full res
As the cold front encroached upon Canadian border states of the Northern Plains overnight, close examination of the GOES-East Nighttime Microphysics RGB (Figure 2) revealed the exact location of the arctic cold front by way of rapidly advancing, arching area of low stratus towards the south embedded or underneath mid-upper level clouds moving northeastward. Higher clouds were associated with a weak mid level and surface wave moving east along the strong baroclinic zone charging southward.
Figure 3: 12 Feb 2020 GOES-East Nighttime Microphysics RGB – Annotated with frontal position and METARs. Full res
Figure 3 annotates the location of the arctic cold front as well as METAR observations with the Nighttime Microphysics RGB. Closely scrutinizing satellite imagery for any subtle details can help forecasters latch onto synoptic and mesoscale features, particularly those that bring hazardous weather like this arctic front whose impacts started immediately after frontal passage. Rapid temporal tracking of this feature offered by GOES-East could give forecasters details like timing of onset to impacts, something very important to IDSS.
Figure 4: 12 Feb 2020 GOES-East Day Snow-Fog RGB. Full res
As the sun rose on February 12, 2020, forecasters at NWS Grand Forks were anxious to see if blowing snow could be viewed on satellite imagery as area observations, reports, webcams, and radar suggested (as it turned out the crust on snow pack might have been broken north of the aforementioned area of newly felled snow due to very gusty winds exceeding 60 mph aiding to the production of blowing snow). Luckily a GOES-East mesoscale sector was over the FGF area (thanks DMX!) during this time allowing 1 minute imagery to provide the most up to date satellite view available. A look at the Day Snow-Fog RGB (proven to be useful in monitoring blowing snow during the day) gave indications of horizontal convective rolls associated with blowing snow, evident moving out of southern Manitoba into northern North Dakota, but perhaps not as quite obvious for operational usefulness (Figure 4).
Figure 5: 12 Feb 2020 GOES-East Day Snow-Fog RGB. Adjusted RGB composite ranges. Full res
Figure 6: 12 Feb 2020 GOES-East Day Snow-Fog RGB. Adjusted RGB composite ranges. Full res
While the blowing snow plumes were somewhat noticeable in Figure 4, the default Day Snow-Fog RGB composite ranges within AWIPS doesn’t show features well in times of low light, i.e. near sunrise/sunset and near poleward locations in winter. Since all three of the components (0.86 um, 1.61 um, 3.9-10.7um) that make up the Day Snow-Fog RGB are sensitive to solar reflectance, we can adjust the composite ranges of this RGB to become more representative of the little solar reflectance available just after sunrise in this high latitude location. Shrinking the RGB composite ranges from the default (R: 0-100, G: 0-70, B: 0-30) to (R: 0-20, G: 0-15, B: 0-25) allows the forecaster to more clearly see swaths of horizontal convective rolls that make up blowing snow (Figures 5 & 6). Forecasters can adjust RGB ranges on the fly like this to make features easier to track, making it more operationally useful. Just don’t forget to readjust the range as more sunlight becomes available!
Figure 7: 12 Feb 2020 GOES-East Day Snow-Fog RGB. Blowing snow over the Northern Plains. Full res
Figure 8: 12 Feb 2020 GOES-East Day Snow-Fog RGB. Red River Valley of the North topography with lowest elevation under 1600 feet transparent. Full res
Figure 9: 12 Feb 2020 GOES-East Day Snow-Fog RGB. Topography of the Coteau De Prairie/Sisseton Hills toggled. Full res
Figure 7 displays how blowing snow could be tracked on satellite throughout the day as dry arctic air scoured away clouds moving south and east near the front (stratus colored white/lavender as well as some higher cirrus as orange/red). Blowing snow extended all along the Dakotas and Minnesota border with blowing snow seemingly influenced by not only the Red River Valley in eastern North Dakota and northwest Minnesota (Figure 8), but also by the Coteau De Prairie/Sisseton Hills in eastern South Dakota and southwestern Minnesota (Figure 9). Significantly reduced visibility as noted by METARs can be matched with the blowing snow plumes seen funneling down the lower elevation of the Red River Valley (Figure 8) and Buffalo River Valley (Figure 9). Also, cessation of blowing snow can be noted within the Red River Valley as the horizontal convective rolls dissipated north to south in Figure 7. Lastly, blowing snow plumes could be noted advecting southward out of southeastern South Dakota into the relatively snow-free far northeast Nebraska towards the end of the loop in Figure 9.
Analysis of GOES-East imagery during this event provided information on antecedent conditions as well as precise tracking of the arctic cold front and blowing snow causing blizzard conditions behind the front. This information was used directly in operations helping refine the boundary of blizzard warnings and winter weather advisories, social media messaging, as well as IDSS support to core partners of the National Weather Service.
Ideal conditions for the development of heavy freezing spray developed across the coastal waters of the northern Gulf of Alaska, including Cook inlet, on the back edge of a low pressure system during the afternoon/evening of 10 Feb 2020. Analysis of GOES-West water vapor imagery reveals the associated upper level trough exiting to the east as the next system approaches from the west (Fig 1).
Figure 1: 10 Feb 2020 GOES-West 6.9 um water vapor imagery and GFS mslp analysis. Point A marks the region of freezing spray. Better res
Given the expected surface conditions, NWS Anchorage issued a Heavy Freezing Spray Warning for the associated offshore waters zone (Fig 2).
Figure 2: 10 Feb 2020 NWS Anchorage Coastal Waters Forecast for region of interest.
During the late afternoon and early evening of the 10th, surface observations indicated the development of gusty winds, temperatures well below freezing, and rough seas; all conditions necessary for the development of freezing (salt water) spray. Gusty winds and temperatures well below freezing were reported at Stations AUGA2 and AMAA2 (Fig 3), with wave heights of 10-15 ft reported at 46080. This is the region within which heavy freezing spray was expected and likely occurred based on analysis of VIIRS and ABI satellite imagery.
Figure 2: Station locations of data shown in Figure 2. Click to enlargeFigure 3: 12 UTC 10 – 12 UTC 11 Feb 2020 wind data (left) and temperature data (right) for AUGA2 (top) and AMAA2 (bottom). Gray region is period of GOES and VIIRS imagery shown below. Click to enlarge
Given the relatively high latitude of the region, three VIIRS passes (one from NOAA-20, two from SNPP) were available during the day within 2.5 hours of each other. The five 375 m I bands from SNPP VIIRS for 2123 UTC are shown in Fig 4, centered over the region of freezing spray. A modified gray scale color table was created to focus on the reflectance values of the spray. The higher spatial resolution of the VIIRS imagery (vs GOES) captured the phenomenon in enhanced detail, allowing for easier diagnosis as to where freezing spray was occurring at that moment. The spray is observed as a region of relatively high reflectance (lighter gray) vs lower reflectance open sea extending from station AUGA2 through Cook Inlet and station AMAA2 into western portions of the broader Gulf of Alaska. Viewing VIIRS 375 m channels I1 – I3, it is obvious that the spray is most apparent in channel I2 given the relatively high reflectance of the lofted sea particles over the very low reflectance ocean surface.
Now viewing I4 and I5, the spray has a higher brightness temperature (darker gray) in the I4 (3.9 um) channel vs I5 (11.45 um) channel as a result of added reflectance component during the daytime due to scattering of the airborne particles. The brightness temperatures are similar in areas of clear sky with no spray over the ocean. Taking the difference between the two channels provides a clear view of where the spray is occurring. Sea current patterns are also apparent in bands I4 and I5, and are differentiated from the sea spray, particularly in band I4 where the spray has a higher brightness temperature, and currents have a lower brightness temperature.
Figure 4: 2123 UTC 10 Feb 2020 SNPP VIIRS I bands 1-5 and band 4 minus 5 difference (left to right, top to bottom). Higher res: I1 (0.64 um), I2 (0.865 um), I3 (1.61 um), I4(3.74 um), I5 (11.45 um), I4 – I5. Color table: low reflectance and warmer brightness temperatures is dark gray, high reflectance and cooler brightness temperatures is light gray. For the I4-I5 difference, dark gray represents a greater positive difference, light gray is near 0 difference.
Imagery from the three daytime VIIRS passes (2038 UTC from NOAA-20, 2123 UTC and 2306 UTC from SNPP) provides a sense of evolution of the spray during the day at high spatial resolution (Fig 5). Clouds appear to have developed within the region of spray by 2306 UTC.
Figure 5: 10 Feb 2020 NOAA-20 and SNPP VIIRS I2 (0.865 um) imagery. Higher res
GOES-West Full Disk sector provided high temporal resolution imagery over the region of lofted sea particles. At such a high latitude, the imagery spatial resolution is degraded (pixel area increases by roughly 4x), but still useful for detecting the spray in a broad sense. Given our analysis of the VIIRS imagery, we take a look at the 1 km (at nadir) 0.86 um band from GOES-West, and are able to track the evolution of the sea spray through the afternoon (Fig 6). A similar color table is used to that presented with the VIIRS imagery.
Figure 6: 10 Feb 2020 GOES-West 0.86 um imagery. Higher res
The CIRA Snow/Cloud product was very effective at capturing the spatial extent of the sea spray without needing to make any modifications (Fig 7). The integrity of the RGB for tracking other features is, therefore, maintained.
Figure 7: 10 Feb 2020 GOES-West CIRA Snow/Cloud product imagery. Higher res
The ability to detect and track sea spray could be useful to NWS forecasters in verifying forecast products such as a Heavy Freezing Spray Warning, and for issuing new forecast products.
A shortwave trough digging into northern Mexico on 5 Feb 2020 brought gusty winds to the surface, leading to areas of lofted blowing dust, primarily from sources marked at points A and B (Fig 1). The lofted dust had traveled as far as Houston, TX, per media reports of dust being deposited at the surface.
Figure 1: 5 Feb 2020 GOES-East 6.2 um water vapor imagery. Points A and B mark source regions of lofted dust and are described in the next paragraph. Higher res
There were two regions in particular from which a significant amount of surface material was lofted and subsequently carried a long distance. These locations, marked in Fig 2 and 3, include red earth from central Zacatecas (point A), and sand from southwest Coahuila (point B), where many sand dunes are present.
Fig 2: Google Maps satellite view of of blowing dust region with significant dust sources highlighted as point A and point B.
Fig 3: Google Maps map view of of blowing dust region with significant dust sources highlighted as point A and point B.
GOES-East 5-min CONUS imagery captured the onset of lofted dust from the aforementioned regions, along with it’s evolution as it wrapped around the southeast portion of the trough and was carried northeast into south Texas. The high spatial resolution afforded by the 500 m 0.64 um visible band provides the most detailed look of the lofted dust as it elaves it’s source, particularly toward sunset (Fig 4). Figure 5 provides a zoomed in look at lofted dust from the red earth (point A) region.
Figure 4: 5 Feb 2020 GOES-East 0.64 um VIS over north-central Mexico. Higher resFigure 5: 5 Feb 2020 GOES-East 0.64 um VIS over centered over point A (discussed above) in north-central Mexico. Higher res
The Geocolor product developed at CIRA combines Channels 1, 2, and 3 and additional computations (making up for the lack of a green channel) to create pseudo-true color imagery during the day. In this case, the daytime geocolor imagery captured the dust plumes quite well, and differentiated the lofted red earth (shades of red) from the red earth region in the south and lofted sand (tan/gray) from the sand dune region to the north (Fig 6). The two source regions also appear red and tan, respectively.
Figure 6: 5 Feb 2020 GOES East CIRA Geocolor product. Higher res
Infrared imagery can also be used to capture lofted dust. The 10.3 – 12.3 um split window difference, previously discussed here for detecting dust, provides a very clear dust signature (negative difference values, dark gray to black; Fig 7).
Figure 7: 5 Feb 2020 GOES-East 10.3 um minus 12.3 um split window difference centered over north-central Mexico. Higher res
Including the split window difference in the Dust RGB, along with the SO2 difference and 10.3 um IR window band, allows for dust detection (bright magenta to pink) along with cloud classification (Fig 8).
Figure 8: 5 Feb 2020 GOES-East Dust RGB centered over north-central Mexico. Higher res
A daytime SNPP VIIRS pass at 1926 UTC over the area provided high resolution still images of the lofted dust from the red earth region shortly after onset. Similar products are available as above, but with better spatial resolution and slightly difference spectral specifications (Figs 9-13). Recall, the I bands provide the highest spatial resolution (375 m), while M band imagery is 750 m.
Figure 9: 1926 UTC 5 Feb 2020 SNPP VIIRS band I1 (0.64 um VIS). Higher res
Figure 10: 1926 UTC 5 Feb 2020 SNPP VIIRS I4 (3.74 um) minus I5 (11.45 um) 375 m imagery. Higher ResFigure 11: 1926 UTC 5 Feb 2020 SNPP VIIRS True Color RGB using M bands 5-4-3. Higher resFigure 12: 1926 UTC 5 Feb 2020 SNPP VIIRS Split Window (M15 – M16) Difference. Higher resFigure 13: 1926 UTC 5 Feb 2020 SNPP VIIRS Dust RGB using M bands 14-15-16. Higher res
Continuing the GOES-East IR-based detection animations into the overnight hours (SWD in Fig 14, Dust RGB in Fig 15), detection becomes difficult as the lofted dust becomes increasingly dispersed, and cloud cover increases. However, careful analysis of the imagery allows one to diagnose the plumes extending northeast across southern Texas through the evening, with the faint remnants of the southern plume making it well up the Texas Gulf Coast.
Figure 14: 5-6 Feb 2020 GOES-East SWD. Higher resFigure 15: 5-6 Feb 2020 GOES-East Dust RGB. Higher res
Feature relative animations (such as when using feature following zoom in AWIPS) provide an intriguing alternative for viewing features in satellite imagery. Such features may include thunderstorms, boundaries, snow bands, dust, and smoke. Closed cellular convection is yet another feature for which a feature relative animation allows for a clearer picture of relevant processes. From the example on 4 Feb 2020 over the eastern Pacific, the divergence from the center of each cell is obvious, painting a picture of the implied rising air in the center of each cell (higher reflectance areas), and sinking air around the edges (low reflectance).
Figure 1: 4 Feb 2020 GOES-West VIS, feature-following zoom. Full res
The same features are highlighted in Figure 2, but over a static region.
Figure 2: 4 Feb 2020 GOES-West VIS, static region. Full res
A zoomed out view of the region shows the development of the above closed cellular convection (in the middle of the scene) within a broader eastern Pacific Ocean anti-cyclone (Fig 3). Open cellualr covnection is also present in this scene, further to the southeast.
Figure 3: 4 Feb 2020 GOES-West VIS, static region, centered over the features discussed in Fig 1-2. Full res
A longer animation (Sunday – Tuesday) shows the full evolution of the features behind the early week US trough and surge of cooler air and within the building eastern Pacific anticyclone (Fig 4).
Figure 4: 4 Feb 2020 GOES-West VIS and IR, static region, centered over the features discussed in Fig 1-2. Full res
A mid-upper level trough brought a variety of weather to the US during the first week of Feb 2020.
On 31 Jan, GOES-West WV imagery captured the early evolution of the trough over the central Pacific while a ridge was well established over the western US (Fig 1). Blending the satellite imagery with a model forecast not only allows one to guage model performance, but also provides a visualization of how features apparent in the imagery may evolve into the forecast period.
Figure 1: 29 Jan – 6 Feb 2020 GOES-West Water Vapor Imagery and GFS 500 mb height/Vort forecast. Full res
By 3 Feb, The ridge had eroded and the trough had advanced into the Great Basin, developing into a closed low (Fig 2). The periodic image degradation is due to the GOES-17 cooling system anomaly and and approaching vernal equinox.
Figure 2: 31 Jan – 3 Feb 2020 GOES-West Water Vapor Imagery. Better res
The trough had sent a cold front south down the high plains during the overnight hours of the 2-3 Feb, with associated gravity wave perturbations evident in water vapor imagery (Fig 3). Combined with surface obs and RAP surface analyses, rapid pressure rises are apparent in the wake of the front, in addition to winds becoming northerly and then easterly and temperatures dropping considerable.
Figure 3: 2-3 Feb 2020 GOES-East Water Vapor Imagery, RAP sfc MSLP, sfc obs. Better res
Nighttime Microphysics RGB imagery from GOES-West shows the rapid development of low clouds (dull yellow – green) across the high plains as temperatures dropped behind the front and the low levels became saturated. Surface obs also show winds becoming easterly upslope through the evening (Fig 4). Snowfall across the eastern plains to this point had been purely stratiform due to a saturated low layer and easterly upslope flow, per analysis of the RGB imagery.
Figure 4: 3 Feb 2020 GOES-East Nighttime Microphysics RGB Imagery, sfc obs. Better res
After sunrise, cloud analysis is best done using the Day Cloud Phase Distinction RGB (Fig 5). The widespread low stratus deck (cyan) is obvious across the scene and contrasts with snow cover (green), high clouds (red), and clear ground (dark blue). By the end of this period, the upper low had advanced into northeast Utah, spreading stronger large scale forcing east across the Rockies, leading to increasing coverage of convective snow showers (textured reds).
Figure 5: 3 Feb 2020 GOES-East Day Cloud Phase Distinction RGB Imagery. Better res
A vigorous shortwave trough dug southeast out of Canada starting the evening of 19 Jan, continued across the middle of the US from the 20th to 21st, and across and east of Florida from the 21st to the 22nd. A long loop of GOES-East upper level water vapor imagery highlights the evolution and the shortwave as it dives southeast, with sinking and drying air (warm colors) on it’s western periphery, and rising and moistening air (white to green colors) to it’s east (Fig 1).
Figure 1: 0000Z 20 – 1500Z 22 Jan 2020 GOES-16 UL Water Vapor Imagery. Full res
Zooming in to the southeast US as the storm moved offshore during the night of the 21st to the morning of the 22nd, significant strengthening of the shortwave is observed as thunderstorms in the ascending region and drying in the descending region both become more pronounced (Fig 2). Relevant large scale features are highlighted at the end of the period.
Figure 2: 2336Z 21 – 1551Z 22 Jan 2020 GOES-16 UL Water Vapor Imagery. Full res
An alternative view of the strengthening is provided in the Airmass RGB imagery from GOES-16. The shades of red becoming more apparent on the western side of the storm represents sinking/drying/higher PV air into the upper troposphere (Fig 3).
Figure 3: 2336Z 21 – 1551Z 22 Jan 2020 GOES-16 Airmass RGB Imagery. Full res
The upper trough was accompanied by anomalously dry air and cold temperatures for the southeast US. Cooling temperatures can be visualized by the GOES-16 Land Surface Skin Temperature product, with skin temperatures across south Florida falling from the 70s during the day of the 21st to 30s during the evening (Fig 4).
Figure 4: 1746Z 21 – 1131Z 22 Jan 2020 GOES-16 Land Surface Skin Temperature (color overlay) and UL water vapor imagery (gray underlay). Full res
The dry air is simialrly captured in the GOES-16 TPW product, with values across much of south Florida dropping to near or below 0.3″ (Fig 5).
Figure 5: 1746Z 21 – 1131Z 22 Jan 2020 GOES-16 Total Precipitable Water (color overlay) and UL water vapor imagery (gray underlay). Full res
This drying was also captured in radiosonde data, with the 12Z sounding from Key West measuring 0.3″ of TPW (Fig 6), which is well below average (1.2″) and actually is a new daily min for that location (Fig 7).
Figure 6: 1200Z 22 Jan 2020 KEY Radiosonde. From SPC. Full resFigure 7: 12Z KEY Radiosonde Climatology for TPW with 1200Z 22 Jan 2020 value highlighted. From SPC. Full res
A surface low and intense and nearly stationary convection associated with the shortwave was captured in GOES-16 visible imagery and GLM Flash Extend Density data during the day on the 22nd (Fig 8).
Figure 8: 22 Jan 2020 GOES-16 VIS and GLM FED. Full res
A fast-moving shortwave trough brought a quick shot of wintry precip to parts of the Upper Midwest during the early part of 15 Jan. With an associated surface low pressure departing into the Ohio Valley, and high pressure building in from the west, northwest winds gusting to around 30 mph developed across the region.
The gusty northwest winds lofted snow off of the ground, causing areas of blowing snow and leading to reduced visiblities under otherwise clear skies across southern Minnesota and northern Iowa during the afternoon and early evening of 15 Jan. Bands reminiscent of cloud streets associated with the areas of blowing snow could be diagnosed in GOES-16 imagery. First analyzing the 0.64 um VIS, the bands of lofted snow area not obvious, but shadowing, especially later in the day, and the high (500 m) resolution of the band allowed for detection of the features (Fig 1).
Figure 1: 15 Jan 2020 GOES-16 0.64 um VIS. Full res
The 1.6 um “snow/ice” band has been shown to effectively highlight areas of lofted snow (blowing snow) from the clear sky. The reflectance of the lofted tiny ice particles is typically between that of snow/ice on the surface (lower reflectance) and low liquid clouds (higher reflectance). Therefore, the lofted ice (over snow) can be more easily identified in the 1.6 m band vs the 0.64 um band, despite having a lower (1 km) spatial resolution.
Figure 2: 15 Jan 2020 GOES-16 1.6 um near-IR. Full res
Combining the aforementioned two bands with the 10.3 um IR window band in the Day Cloud Phase Distinction RGB, we get an even better picture of the blowing snow. The lofted ice is identified as a dull cyan above the surface snow (green) and adjacent to the low liquid water clouds (bright blue).
Figure 3: 15 Jan 2020 GOES-16 Day Cloud Phase Distinction RGB. Full res. With controls.
The Day-Snow-Fog RGB, which also includes the 1.6 um band (along with 0.87 um and 3.9 – 10.3 um difference), has been discussed as an effective means of identifying and tracking blowing snow. The contribution from 1.6 um band is the main driver behind the detection, with slight contribution from the other two components. For blowing snow detection, we replace the 0.87 um component with the higher resolution 0.64 um visible channel in order to capture finer details in the blowing snow bands.
Figure 4: 15 Jan 2020 GOES-16 Day Snow-Fog RGB with 0.64 um VIS substituted for 0.87 um near-IR. Full res. With controls.
Slight modifications were made to the RGBs in order to better highlight the feature of interest. The recipes used in this post are shown in figure 5.
Figure 5: RGB recipes used in figure 3 (left) and figure 4 (right). Full res.
Finally, a SNPP overpass during the early afternoon allowed for high resolution VIIRS imagery of the blowing snow bands to be collected. The 375 m 1.61 um band (I3) provided a great depiction of the blowing snow “streets” across the region.
1922 UTC 15 Jan 2020 SNPP VIIRS 1.61 um band. Shades of blue represent higher reflectance (water clouds), dark gray to black is lowest reflectance (snow cover). Northwest to southeast oriented blowing snow streets are apparent in the middle of the scene as a relatively light gray above the darker surface. Full res
A compact shortwave trough brought widespread severe weather to the southern US 10-11 January 2020. A Moderate Risk for severe storms was issued by the Storm Prediction Center for 10 January for a significant severe wind gust threat, with secondary threats of large hail and tornadoes. The threat on the 10th was centered over Texas, Oklahoma, Arkansas, and Louisiana, shifting east to Mississippi/Alabama on the 11th.
GOES-West upper-level water vapor imagery during the 48 hours leading up to convective development on the 10th show the evolution of the shortwave trough from off the northwest US coast, south along the west coast, and then east across the southwest US and into Texas (Fig 1).
Figure 1: 10 January 2020 GOES-West 30-min upper level water vapor imagery. Higher Res
The potent system drove enhanced low-level moisture into the region along with strong mid-upper level winds. This VISIT blog post highlights the utility of layer PW products for tracking the evolution of moisture and the EML leading up to the convective event.
Convection was ongoing/developing across Oklahoma during the morning/early afternoon on the 10th. Further south into Texas, convection developed a little later during the afternoon as the upper trough and associated strong forcing shifted closer, and inversion associated with the EML eroded.
By the late morning, GOES-16 derived motion winds indicated a swath of 60-70 knot SSW winds around 6 km AGL out ahead of the trough across north Texas (prior to CI here). Using the satellite-derived winds in combination with surface obs below to compute a vector difference, we achieve 0-6 km bulk shear values of around 55 knots, supporting the development of supercell thunderstorms (Fig 2). Further, the strong unidirectional deep layer flow is parallel to the surface/low-level boundary as diagnosed in visible imagery and surface obs (SSW to NNE). This orientation along with the strong shortwave forcing imply a likelihood of linear thunderstorm mode and wind threat quickly upon development.
Figure 2: 1726 UTC 10 Jan 2020 GOES-16 VIS, DMW wind barbs. Full res
GOES-16 1-min Day Cloud Phase Distinction RGB imagery showed widespread low stratus clouds (cyan) and showers (darker green indicating ice in cloud) across north Texas by early afternoon (Fig 3). During this period, convection rapidly develops southward across the region, clear in the 1-min RGB imagery per the vertical growth and transition to reds and yellows (result of cooling in the IR and increasing reflectance in the VIS as convection deepens).
Figure 3: 10 January 2020 GOES-East 1-min Day Cloud Phase Distinction RGB imagery. Higher Res
Now looking at 1-min VIS/IR sandwich imagery for the following hour, convection continues to grow quickly southward across north Texas (Fig 4). The sandwich imagery maintains the high resolution/detail available in the 500 m VIS, while also representing the degree of cooling via the IR. Important storm to features are also easily detectable, including overshooting tops and above anvil cirrus plumes.
Figure 4: 10 January 2020 GOES-East 1-min VIS+IR sandwich imagery and NWS warning polygons. Higher Res
During this same period, VIS/GLM FED sandwich imagery showed lightning jumps with the strongest storms embedded in the broader line during early development (Fig 5). The north Texas storm for which a severe thunderstorm and tornado warning was issued saw lightning activity increasing from around 20 fl/5-min to around 90 fl/5-min within a ~15-minute period leading up to warning issuance. This rapid increase in flash density signifies a rapidly intensifying updraft. This particular storm had 1″ hail reported with it.
Figure 5: 10 January 2020 GOES-East 1-min VIS and 5-min GLM Flash Extent Density imagery and NWS warning polygons. Higher Res
Analyzing 1-min visible imagery even further south, storms continued to develop south along a narrow line. The low sun angle allows for easy diagnosis of vertical growth as well as relevant storm top features such as overshooting tops and eventual above anvil cirrus plumes. Ahead of the developing storms, billow cloud formations indicate the continued presence of a stable layer inhibiting surface base convection.
GOES-16 1-min visible imagery depicts rapidly developing narrow line of strong convection across central Texas by late afternoon on Jan 10. #txwxpic.twitter.com/KmU0P01Kvd
