hydrology, weather

South Florida Rainfall Records Going Under Water (H. Michael Mogil, CCM, CBM, NWA-DS*)

A few days ago, I noted that southwest Florida “rainfall for June 2017 (now almost only half over) was at rarified levels.” Since I’ve had a chance to compare observed rainfall to longer-term records (using the NOAA Regional Climate Center data base), it is clear that the deluge so far this month has started to submerge many existing records.

Recognize, however, that many locations do not have official long-term records; hence, the numbers shown for record comparisons are limited to only a few sites. And, even for some of these, records are rather short-term. Regardless, the numbers are more than impressive across the entire region. They are even more impressive when one realizes that less than a month ago, everyone was worried about drought and forest fires!

Looking at a radar – rain gauge data mix (Fig. 1), it is easy to see where the heaviest rainfall has occurred. Collier and Broward Counties have some locations with an excess of 20 inches so far this month.

Thus far this month (through early morning on Jun.18, 2017), Naples Airport, FL (APF) has received 11.40 inches of precipitation. The average for the entire month of June is about 8.80 inches. Based on the Naples area period of record (1942-2017), the 11.40 inches ranks 17th on the list of highest monthly amounts. The record June rainfall occurred in 2005 (20.51 inches); the second highest amount was recorded in 1947 (17.97 inches).

Regional Southwest Airport (RSW) in Fort Myers has received 12.96 inches so far this month, making this the 5th wettest June at RSW (records have been kept there only since 1998). The record occurred in 2005 (20.85 inches).

With an even shorter period of record, Marco Island has already measured 20.90 inches of rain this June. The record (25.21 inches) also occurred in 2005.

Rainfall, year-to-date, at Marco Island is now at roughly 60% of the total average yearly rainfall of about 50 inches.

Given the weather pattern that we are in and the abundant tropical moisture supply, it is likely that some of these long-term records could be challenged and broken as the month continues. And, to think, there’s still 13 days left in the month!

© 2017 H. Michael Mogil

Originally posted 6/18/17

* The National Weather Association Digital Seal (NWA-DS) is awarded to individuals who pass stringent meteorological testing and evaluation of written weather content. H. Michael Mogil was awarded the second such seal and is a strong advocate for its use by weather bloggers.

oceanography, weather

A major source of a hurricane’s energy

Everyone knows something about tropical cyclones, the broad class of tropical low-pressure systems that includes hurricanes and typhoons (Fig. 1). Many of us know when and where they are more likely to form and how they are named. If you were asked about the most favorable conditions under which these tropical systems develop, among the first things you would probably say would be sea surface temperature. Some of you may also know that a sea surface water temperature above about 80oF is a very favorable factor. No wonder that hurricanes form over low-latitude ocean areas.

A hurricane or its antecedent weather system could be thought as an engine, drawing heat energy from the water body underneath it. The system does this in two ways. First, air touching warm water is warmed by contact (conduction), and air heated from below wants to rise (convection)*. Second, water evaporates from the warm ocean surface (with latent heat trapped in the water vapor) and is then carried upward by rising air currents (updrafts). The latent heat is released during the phase change from water vapor to water droplets (condensation and cloud formation) and that heat is then distributed vertically within the updraft (Fig. 2).

Now, think about a weather situation modeled in your kitchen. Imagine that you have a bowl with hot, steaming soup. Would you rather cool it down by blowing on the whole bowl or a small portion of the soup in a spoon? Almost everybody would choose the second option. Well, now think about the force of the winds in a hurricane. Don’t you think they are strong enough to lower the water temperature? And if you take also into account the large amounts of chilled precipitation that falls on the ocean surface, then you would realize that we need something else to keep providing the necessary energy for hurricanes.

The depth of the isothermal layer (a layer in the ocean that has an almost constant temperature) plays an important role in sustaining and intensifying hurricanes and tropical cyclones. Considering its depth and its temperature, we could then estimate the available potential energy for the hurricane’s heat engine. It is important to note that the hurricane circulation is strong enough and its pressure low enough to actually lift the surface of the ocean, causing deeper layers with a lower temperature to rise, thereby squeezing this isothermal layer somewhat. Depending on the strength of the storm’s circulation, how low the atmospheric pressure is in the center of the storm, and the storm’s speed of motion, the effect can be quite strong. It could possibly even generate a cool surface water “footprint.”  Obviously, such cool “footprints” can weaken a hurricane.

Conversely, we can say that there must be certain areas where a tropical cyclone could intensify. Tropical meteorologists call these “warm pools.” Forecasters can monitor these and ascertain how they affect a hurricane’s growth and/or intensification.

*Sensible heat is almost negligible, since it depends of the temperature difference between the water surface and the air, which in the tropics is usually less than 1oC ( Emanuel, K: The theory of hurricanes, 1991).

© 2017 Mayguen Ojeda

Originally posted 6/17/17

climate, weather

More heavy rainfall for southwest Florida (H. Michael Mogil, CCM, CBM, NWA-DS*)

Rainfall for June (now almost only half over) is already at rarified levels. Many locations across southwest Florida have logged 15 to 20 inch values. And more rainfall is anticipated.

In fact, for the Naples area (my home base), the official National Weather Service (NWS) forecast is calling for 50 to 70 percent daytime rainfall probabilities each day for the next week.

And, no wonder. The atmosphere above the now, so-called “Sunshine State,” is overburdened with moisture (Fig. 1). According to NOAA’s (National Oceanic and Atmospheric Administration)’s Storm Prediction Center (SPC), precipitable water (PW) was at 1.92 inches at Miami, FL early this Thursday morning. PW is the measure of all water vapor in a column above a radiosonde (weather balloon) sounding location. For Jun. 15, the climatological average PW at Miami, FL is 1.66 inches and a 90 percentile PW is 2.00 inches. In short, if all the water vapor above a point could be condensed into liquid water and then squeezed out (like a sponge), and no water vapor moved in or out of the atmospheric column, 1.92 inches of rain would result.

Further, winds throughout the atmospheric column from the ground to some 50,000 feet above ground level are less than 15 miles per hour. That means that any storms that develop will not move very fast.

While outflow boundaries (areas marking where low-level winds blowing out of thunderstorm areas meet the environmental air mass) may interact with other outflow boundaries and sea breezes to enhance thunderstorm formation or localized movement, most storms will be slow-moving, prolific, rainfall producers. Many locations could see short-period downpours of one to two inches or more during the upcoming week or until the weather pattern changes.

© 2017 H. Michael Mogil

Originally posted 6/15/17

* The National Weather Association Digital Seal (NWA-DS) is awarded to individuals who pass stringent meteorological testing and evaluation of written weather content. H. Michael Mogil was awarded the second such seal and is a strong advocate for its use by weather bloggers.

technology, weather

Tornado watchers from the sky

Last November, a new weather satellite (GOES-R*), was launched from the Kennedy Space Center in Florida (Fig. 1). This new space dweller is equipped with modern and powerful instruments, opening numerous possibilities for improved weather analysis and forecasting.

Today, I would like to focus on a brand-new instrument – The Geostationary Lightning Mapper (GLM). Scientists believe that this could be the key to improved tornado forecasting.  Studies have shown that there is a positive relationship between changes in the lightning pattern inside a storm and the formation of a tornado. But, before we get into that, let’s talk about thunderstorm formation, particularly that of tornadic thunderstorms.

In areas with vertical differences in wind direction and speed (what meteorologists call wind shear), there is a potential for the formation of horizontal rolls (Fig. 2).

When a powerful thunderstorm develops, the lifting air associated with it tilts these rolls, turning them into more vertical positions (one with rising air and one with sinking air) as shown in Fig. 3.

Under some circumstances, the upward rotation can extend to the ground generating a violent column of rotating air, known as a tornado. Unfortunately, there are still limitations to pin-pointing the onset or potential onset of tornado formation (i.e., the warning process). Severe weather forecasters typically recognize the larger-scale conditions and general geographic areas in which tornadoes can possibly form (watch process).

Once a watch is issued (or localized conditions suggest possible tornado or severe weather development), storm spotters and Doppler radar become the key tools available to local National Weather Service forecasters. Trained spotters can recognize cloud features that suggest possible severe weather. Radar, however, can probe the interior of the thunderstorms. Determining the presence of certain echoes (radar patterns based on the size and distribution of water droplets) can indicate the presence of a rotating core that is often linked to the occurrence of tornadoes.  Doppler radars are also capable of detecting areas of rotation (based on the wind movement toward/away from the radar).  Still, radars have limitations regarding vertical and horizontal coverage and resolution. At large distances, the radar may even “overshoot” the tornadic circulation, passing high above it. So, depending on the distance from the storm to the radar and other factors, forecasters may not be able to detect a tornadic signature.

Recent research indicates there is a close relationship between lightning and tornado formation. A considerable and sudden increase in lightning flash rates (lightning frequency), known as a “jump,” has been observed to take place just before tornado formation. These jumps have been registered 20-25 minutes before the tornado occurs (i.e., about 10 minutes more than the current average tornado warning lead-time). Until now, the only possible way to measure the lightning activity inside the storms, was to use the National Lightning Detection Network, which was the most accurate way to record time, strength and number of strokes of cloud to ground lightning flashes. But, the more intense and severe the storm is, the more important the intra-cloud lightning (cloud to cloud strokes) may be.

That is why the meteorological world is celebrating the launch of GOES 16. This satellite is opening new ways to make huge advancements in weather observing, analysis and forecasting. With the arrival of the GLM, the satellite is capable of detecting intra-cloud, cloud-to-ground and cloud-to-air lightning.

With the 2017 tornado season well underway, scientists have already been looking at GLM’s capabilities and reliability in detecting tornadoes.

*The name of the satellite was changed from GOES R to GOES 16, once the spacecraft reached its stationary orbit on November 29th.

© 2017 Mayguen Ojeda

Originally posted 6/14/17

weather

Funnel cloud in Naples (H. Michael Mogil, CCM, CBM, NWA-DS*)

At around 7:30 p.m. E.D.T. this Friday evening, my wife and I spied a well-formed funnel cloud west of our location in North Naples, FL (Fig. 1). The funnel was likely near or just offshore from Vanderbilt Beach. Radar images showed a developing shower or thunderstorm near the funnel’s location (Fig. 2).

About 15 minutes later, the lowered cloud base associated with the funnel had moved to our northwest and the funnel was difficult to see behind a grove of palm trees. At this time, the funnel was becoming wrapped in rain.

© 2017 H. Michael Mogil

      

weather, weather safety/preparedness

More Naples, FL area wildfires (H. Michael Mogil, CCM, CBM, NWA-DS*)

Late Thursday, Apr. 20, 2017, two wildfires of unknown origin broke out in the Golden Gate Estates area of east Naples, FL. Although fire fighters jumped into action quickly, dry and windy conditions allowed the fire to spread. By this morning, the combined blazes had grown to about 2,500 acres.

Collier County Emergency Management issued evacuation orders for some limited areas yesterday and expanded areas affected during today. As of late this afternoon, the boundaries of the evacuation area extended from the south side of Golden Gate Boulevard south to the east-west portion of I-75 and from Collier Boulevard east to Wilson Boulevard.

Jim Dickey, WZVN-TV (CH 7 – ABC, Fort Myers) Certified Broadcast Meteorologist, posted radar imagery at around 10:00 a.m. E.D.T. today of the dual fires at his Twitter page (@WxDockey). Dickey noted that “Now that A.M. inversion has lifted, smoke plumes from #30thStFire and #FrangipaniFire visible on radar” (Fig. 1).

     Images from the Immokalee Fire Control District showed the scope of the fires and their associated large billowing smoke clouds (Fig.2 and Fig. 3). Overnight and during Friday morning, the smoke reached the Naples City limits, lowering visibility at the Naples Airport (KAPF) to 3 miles. Based on the trajectory of the plume this morning (WZVN-TV radar imagery and video), and the fact that the smoke plume is still showing up on the Miami National Weather Service radar late this afternoon, most of western Collier County (including the city of Naples) and parts of southern Lee County are going to be experiencing smoky conditions through tonight and into early Saturday morning.

Thus, smoke from the fire will be affecting many more people than the fire itself. Small airborne particles from the fire may lead to respiratory problems, even for healthy people. Check out Fig. 4, a wildfire poster from http://www.ready.gov, republished by Florida Health. It contains some useful tips for dealing with smoky air.

© 2017 H. Michael Mogil

Originally posted 4/21/17

* The National Weather Association Digital Seal (NWA-DS) is awarded to individuals who pass stringent meteorological testing and evaluation of written weather content. H. Michael Mogil was awarded the second such seal and is a strong advocate for its use by weather bloggers.

weather

SWFL-GWCC South Florida’s Cowbell fire grows rapidly (H. Michael Mogil, CCM, CBM, NWA-DS*)

Discovered on Mar. 30, a relatively small brush fire in South Florida’s Big Cypress National Preserve (eastern Collier County) grew slowly during the following week. By Apr. 8, the Cow Bell fire (so named, because it is near the Cow Bell Strand within the Big Cypress National Park – Fig. 1) had consumed roughly 600 acres. On Sun., Apr. 9, thanks to an increase in easterly winds (and continued dry weather), the blaze exploded. By late Sunday, the blaze had consumed more than 8,000 acres. For comparison, this fire is slightly larger than the burned acreage from the Picayune Strand Fire (western Collier County) back in early- to mid-March. Fig. 2 shows the smoke plume from just north of the Cow Bell fire area.

During much of its lifetime, the fire has been moving westward across “Alligator Alley,” mostly parallel to Interstate Highway (I-75). Campgrounds in the Bear Island area, within the Preserve, are being evacuated. Due to the rapid spread of the fire, fire-fighting crews have had to reassess possible containment lines for stopping the fire’s westward movement.

Maximum smoke impacts were expected closest to the fire, with smoke also impacting I-75 between mile markers 55 through 80. On the evenings of Apr. 9 and 10, around sunset, smoke smell permeated the air in parts of North Naples (more than 50 miles from the fire). Smoke from the fire was also evident in the skies over North Naples. Fig. 3 shows the smoke plume as shown on the NWS Miami radar during mid-afternoon on Apr. 9.

Lacking any rainfall for the foreseeable future, and given the pineland and cypress habitat that is ablaze, the hundreds of fire-fighters engaged in battling the fire will have their hands full. Fortunately, there are only a few structures anywhere near the fire area, at this time.

Officials have urged all drivers on I-75 to use extreme caution and to check road conditions before starting travel across the “Alley.” The highest likelihood for experiencing roadway visibility restrictions due to smoke will be between 4:00 a.m. and 8:00 a.m. daily. This is the time window during which an inversion, a low-level temperature pattern with warmer air overlying cooler air, is most likely to trap smoke near the ground.

Big Cypress National Preserve officials have instituted the following closures:

  • Gator Head Campground
  • Bear Island Campground
  • Jeep Campground
  • The road leading into the Sanctuary except to residents
  • All trails between state road 29 and L-28 Canal including the Florida Trail
  • All public lands west of the L-28 Canal
  • All public lands east of state road 29
  • All public lands south of the Preserve boundary
  • All public lands north of Alligator Alley

In addition, a temporary flight restriction has been placed over the Cowbell Fire (ground level to 3,000 feet mean sea level) to provide a safe environment for fire-fighting aviation operations. In addition to 17 fire engines, at least seven helicopters and two water tanker aircraft are involved in firefighting efforts. The area will likely be expanded to accommodate increased fire growth.

© 2017 H. Michael Mogil

Originally posted 4/11/17

* The National Weather Association Digital Seal (NWA-DS) is awarded to individuals who pass stringent meteorological testing and evaluation of written weather content. H. Michael Mogil was awarded the second such seal and is a strong advocate for its use by weather bloggers.

 

weather

Description of the four-panel GWCC home page display (H. Michael Mogil, CCM, CBM, NWA-DS*)

The GWCC home page contains a four-panel graphic containing satellite and radar observations and a severe weather outlook (all from NOAA). The following is a brief overview of these graphics (organized by column from left to right):

  • GOES Enhanced Infrared satellite image (upper left) – This image, obtained by a GOES (Geostationary Operational Environmental Satellite) measures the “heat” given off by clouds, large water bodies, land surfaces, and clouds. Using a special “enhancement” scale (see color bar at the bottom of the image, just below the NOAA logo), warmer colors appear as blues and greens and colder temperatures appear as yellows and reds. Note, that GOES satellite images on different web pages (or in different GWCC posts) may use different enhancement or “false color” image temperature scales. Colorized images, such as these, should always have their own color key.
  • GOES Water Vapor satellite image (lower left) – This geostationary satellite image also measures “heat,” but the satellite sensors used are more sensitive to the amount and distribution of atmospheric water vapor. When the atmosphere at the middle and high altitudes is dry, infrared energy from lower altitudes (where temperatures are normally warmer) is able to escape to space and be detected by the GOES (Geostationary Operational Environmental Satellite) sensors. This image has been false-colored using a special “enhancement” scale: dry (black and orange), mid- and high-level moisture (white), and cloud-laden at mid- and high-levels (blue and green through red and purple).
  • Storm Prediction Center (SPC) convective outlook (upper right) – SPC issues a wide array of severe weather and other thunderstorm-related guidance and outlook products. They also issue tornado and severe thunderstorm watches and fire weather outlooks. This image, which is often updated several times a day, shows expected thunderstorm and severe thunderstorm activity for “Day 1.” “Day 1” extends from the forecast time until the next 1200 GMT (Greenwich Mean Time or 8:00 a.m. E.D.T / 7:00 a.m. E.S.T. Favored areas for thunderstorm / severe thunderstorm activity are depicted as, “to the right of a line,” as shown by an arrow at the end of any line.
  • National radar composite image (lower right) – This image brings together radar reflectivity data from some 100 plus radar sites throughout the contiguous 48 states. Radars measure how much energy atmospheric solids and liquids (hydrometeors such as snow, hail, and rain, as well as particles such as dense smoke and volcanic ash) reflect back to a radar site. The greater the reflectivity value (shown in dBz units), the greater the concentration of so-called “hydrometeors,” solids and other objects (e.g., birds, bats), the radar beam may intercept. The color scale ranges from blues and greens (the lowest reflectivities) to reds and purples (the highest reflectivities).

© 2017 H. Michael Mogil

Originally posted 4/7/17

* The National Weather Association Digital Seal (NWA-DS) is awarded to individuals who pass stringent meteorological testing and evaluation of written weather content. H. Michael Mogil was awarded the second such seal and is a strong advocate for its use by weather bloggers.

weather

Heavy rainfall gradients and rainfall rates (H. Michael Mogil, CCM, CBM, NWA-DS*)

Across Louisiana, Mississippi and parts of far East Texas, torrential rainfall occurred Sunday and Sunday night. Widespread one to four inch rainfall amounts were reported, with some locations noting amounts of six, eight and even ten inches (Fig. 1). Alexandria, LA, in the west-central part of the state, reported more than nine inches over a nearly 12-hour period, with nearly continuous thunderstorm activity for a roughly 8-hour period (Fig. 2).

By early Tuesday, the large-scale storm system responsible for the storminess has moved well to the northeast and the heaviest rainfall had moved well to the east of The Pelican State. In the wake of the Sunday rainfall activity, flood warnings remain in effect for many areas in Louisiana that received excessive rainfall or are downstream from these areas (Fig. 3).

Two things are striking in Fig. 2. First, there are numerous bands of heavy rainfall aligned southwest-to-northeast. These mark the locations in which thunderstorm lines became at least somewhat stationary. Then thunderstorms, moving along the line, dumped successive bursts of heavy rainfall. This scenario, in which numerous storms move across the same area, is known as “training.”

The second thing of note is the large precipitation gradients in areas near the heaviest rainfall. One only needed to have traveled a relatively short distance to go from eight to ten inches of rainfall to amounts of around an inch.

A similar, albeit greater, rainfall gradient occurred in my backyard, Collier County, in southwest Florida, on Sunday. A small convective weather system (without thunder and lightning), developed along the sea breeze front and moved slowly northwestward across parts of north-central Collier County. Heavy rainfall (between 1.47 and 1.78 inches according to two nearly co-located reporting stations) fell just two miles to the northeast of my rain gauge. According to a high school student interested in meteorology (and one

who attended a Naples weather camp last summer), most of the rainfall that he measured fell in just under 20 minutes (Fig. 4). That translates to an hourly rainfall rate of 4.5 inches to 5.5 inches. I measured a scant 0.07 inches of rainfall, although I did briefly experience gusty outflow winds from the convective weather system. Fig. 5 shows radar-based rainfall estimates for southwest Florida on Sunday.

While these situations were somewhat similar in their excessive rainfall and localized rainfall gradients, one was linked to a large-scale low-pressure system and the other to a small-scale sea breeze zone. This is testimony that different meteorological scenarios can yield similar meteorological outcomes.

© 2017 H. Michael Mogil

Originally posted 4/4/17

* The National Weather Association Digital Seal (NWA-DS) is awarded to individuals who pass stringent meteorological testing and evaluation of written weather content. H. Michael Mogil was awarded the second such seal and is a strong advocate for its use by weather bloggers.

geography, weather

A Look at GOES Water Vapor Imagery (H. Michael Mogil, CCM, CBM, NWA-DS*)

This feature is about GOES (Geostationary Operational Environmental Satellite) Water Vapor (WV) imagery. This type of satellite imagery (just one of many) is based on a specific band of data within the infrared radiation (IR) spectrum. It is collected from a geostationary satellite positioned roughly 22,000 miles above the Equator near the longitude of Florida and a longitude just west of the U.S. West Coast. With the satellites racing around their larger orbit path at an angular speed that matches that of the Earth’s surface, the satellite never sees the earth moving (hence, geo- or Earth- stationary). As a result, animations show cloud and/or moisture movement only. These two U.S.-operated satellites are part of a global network of satellites supported by several Nations and/or organizations.

I’m a big fan of WV imagery because it allows meteorologists and others to see the motions (called animations) of clouds and locations of moist/dry areas. Even when the image is not color-enhanced, the various white to black grey shades provide important discrimination. Thunderstorms, with cold, high, cloud tops appear as the brightest white; cirrus (ice crystal) clouds are white, but typically not as bright. Moist areas are generally grey; dry areas are black (see scaling, warm to cold, at lower left of Fig. 1). It would be easy to see this representation as something similar to a topographic or relief map, with thunderstorms representing the mountains and dry zones representing dried lake beds.

In this image (Fig. 1) and associated animation, there is a lot to see. For example, there is a bright area that develops across eastern Oklahoma and moves into southeast Missouri. To its north, it is easy to see a small-scale swirl in the clouds and moisture areas. Further northwest, a larger swirl (the center of the main storm system) was moving into southwestern Minnesota.

Since the WV imagery is based on IR (temperature) data, it is easy to ascertain ground-based features when very dry air covers a region (such as west Texas, New Mexico, Colorado, and western Kansas). Notice the roughly north-line that separates a light grey region to the west and a dark area to the east. This marks the front-range of the Rocky Mountains, with snow-covered, colder mountains to the west and low-altitude, warmer, plains to the east (Fig. 2).Near the end of the animation, a cloud rapidly develops over far west Texas, just to the northeast of El Paso. The western edge of the cloud stays locked in place, as nearby clouds continue to move by from the west. This cloud feature formed as moist air bumped into the Guadalupe Mountains (and Guadalupe Peak, 8751 feet elevation) and was forced to rise (Fig. 3). Rising air cools by expansion (lower pressure as one goes up in the atmosphere) and this often leads to condensation and cloud formation. Since the feature causing the cloud to form doesn’t move, the cloud feature continually reforms on its western edge. From the ground, this would likely appear as a standing wave cloud,

Finally, across New Mexico, notice that some grey clouds move over the snow-covered, colder ground areas. These clouds are warmer than the underlying ground and provide some information about the vertical atmospheric temperature profile in the area.

The bottom line to all of this is that GOES weather satellite imagery allows meteorologists and others to view larger geographic regions and both large- and small-scale weather features.

And this limited perspective of satellite capabilities is just with current GOES capabilities and just one IR channel. Wait until GOES R, launched last November, gets fully checked out and starts to deliver operational data and images. The WOW factor will likely be incredible!

© 2017 H. Michael Mogil

Originally posted 3/1/17

* The National Weather Association Digital Seal (NWA-DS) is awarded to individuals who pass stringent meteorological testing and evaluation of written weather content. H. Michael Mogil was awarded the second such seal and is a strong advocate for its use by weather bloggers.