1. Introduction
During the late night and early morning hours of 22-23 February 1998 (Sunday-Monday), the most devastating tornado outbreak ever to occur in the state of Florida, in terms of both loss of life and property damage, occurred within the National Weather Service Office in Melbourne's (NWS MLB) county warning area. Forty-two people died as a result of the tornadoes and more than 260 others were injured. While outbreaks of strong and violent tornadoes have been documented on occasion in central Florida over the past 100 years, the high death toll was unprecedented. In addition, over 3,000 structures were damaged, while more than 700 were completely destroyed. A total of seven confirmed tornadoes occurred during the night (Fig. 1) approximately between 11 pm and 230 am. Four of these (South Daytona, Winter Garden, Sanford, and Kissimmee) produced long damage tracks of 8, 18, 14, and 38 statute miles respectively, resulting in the majority of damage and all fatalities. Official Service Assessment has estimated three of these tornadoes to have reached F-3 intensity on the Fujita scale with estimated wind speeds around 200 mph (NOAA NWS, 1998). Before sunrise that morning, it was evident that this event was of historical significance (Fig. 2).
This poster will present aspects of the outbreak, beginning
with a review of previous local research concerning favorable outbreak
conditions and the link between El Nino and extreme Florida tornado outbreaks.
These studies were used well ahead of the event to inform the public and
emergency management community of the greater than normal threat for significant
winter and spring tornado outbreaks, and to posture the local NWS for such
occurrences.
The NWS MLB also had real-time access to a multitude of data including
experimental radar and lightning workstations throughout the event, enabling
a more thorough assessment of individual tornadic supercells. Radar reflectivity
and velocity images during various stages of maturity of each associated
storm will be illustrated and compared to concurrent damage photos on the
actual poster. Trends of mesocyclone and tornado vortex parameters will
be presented in relationship to tornado occurrence and parent circulation
occlusion cycles The utility of the National Severe Storms Laboratory (NSSL)
Warning Decision Support System (WDSS) algorithms will be discussed, specifically
the Tornado Detection Algorithm (TDA), which will be available on the official
operational system during later this year. Unique Total Lightning Information
(TLI) signatures will address the horizontal, vertical, and temporal nature
of the electrical discharges associated with the tornado-producing cells.
2. Past Research
Recently, local research has better defined the character and climatology of peninsular Florida tornado outbreaks and their variability (Hagemeyer, 1997). Comparisons and brief case studies of outbreak-types were previously investigated with the intention of providing comprehensive understanding and improvements in forecasting such outbreaks. Additional local research also explored the potential for significant tornado occurrences in Florida during strong El Nino events (Hagemeyer, 1998). It was concluded that during strong El Nino events, the mean position of the southern branch of the winter/spring jet stream is centered much farther south than normal over the Gulf of Mexico and Florida peninsula, and is stronger than normal. This tends to bring greater vertical shear over central Florida and increases the chance that a dynamic environment favorable for significant tornado occurrence will exist over the area. During December 1997, the state of Florida (emergency management) was apprised of this finding in preparation of the 1997-98 winter/spring season with respect to heightening severe weather awareness.
During the evening of February 22, the synoptic situation (Fig.
3) supported the potential for a severe weather outbreak over Florida
and was remarkably similar to the mean pattern as conceptualized by Hagemeyer.
A strong upper trough associated with a 140 kt jet streak was approaching
the peninsula from the west. A surface low was located over Alabama, trailing
a cold front over the eastern Gulf of Mexico with the warm front located
north of the area. This left the peninsula in the warm and unstable sector
in the presence of a developing nocturnal low-level jet with wind speeds
greater than 50 knots just above the surface.
3. Anticipation of Tornado
With recently gained insights relating to Florida tornado outbreaks fresh in the minds of MLB forecasters, the annual training session (local) was conducted in December 1997 instead of early February. The training was centered around radar analysis techniques for the detection and manual assessment of mesocyclones and tornadic mesocyclones. Many of the techniques which have been taught and endorsed by the Operational Support Facility (OSF) were emphasized, but accented with local research results and experience. Training examples were confined to WSR-88D KMLB data. An internal intranet web site (Fig. 4) was prepared which made it possible to exploit the "Tornado Warning Guidance" document comprised of preliminary results of the National Severe Storms Laboratory (NSSL) from project VORTEX. The document was modified to better apply to the east central Florida environment. The emphasis was placed on the higher probability of occurrence situations of radar observed supercells with respect to low-level radial convergence, boundaries, magnitude of rotational velocity, and low-level shear of the core mesocyclone. This "living document" remained available as a training resource and operational guide and was placed on the forecast floor. Forecasters were acute to looking for concentrated mid-level mesocyclone cores and assessing the magnitude of low-level rotational velocity and low-level shear. During the outbreak many of the storms possessed rotational velocities in excess of 45 kts (Fig. 5) and low-level shears greater than 0.015 s-1.
As the event began, numerous developing supercells were embedded within
an approaching (broken) squall line which was moving into a higher theta-e
environment. Storms which seemed to rapidly organize were slightly out
front of the others with unobstructed inflow. New storms formed on the
southwest end of the line and rapidly moved northeast at 50 kts. The first
tornado (F2) occurred in south Daytona Beach around 1055 pm and was associated
with a long-track mesocyclone which was first detected in Sumter County
over one hour earlier. This tornado resulted in 1 fatality and 3 injuries.
The second tornado (F3) formed over south Lake County and quickly moved
into west Orange County through the town of Winter Garden around 1150 pm
where there were 3 fatalities and 70 injuries. This cyclic storm later
achieved tornado two more times moving through the town of Sanford at 1215
am (F3) killing 13 and injuring 36 and then over east Volusia County (F2)
with no deaths or injuries. The Kissimmee tornado (F3) occurred around
1250 am and had the longest track. This tornado killed 25 people and injured
more than 150 where numerous casualties occurred in the Ponderosa RV park
in Kissimmee. This storm also recycled to produce and F1 tornado in north
Brevard County around 138 am but with no casualties. Later, a brief F1
touched down again in north Brevard County near Port Canaveral at 230 am
and also resulted in no casualties. The poster will show the individual
tornadic supercells and the respective radar parameter trends.
4. Experimental Data
There was considerable experimental data available during the event. The WDSS workstation was available most of the time and provided value-added information to warning forecasters. The NSSL tornado algorithm performed very well (Fig. 6) scoring a probability of detection near 100 percent. At this time the false alarm ratio had not been calculated. However, when compared to the current tornado algorithm available on the operational system, it was far superior since the current algorithm only produced one tornado detection on one scan. Also available during the event was an experimental lightning workstation which overlays total lighting information with radar information (Fig. 7). Several of the tornadic storms were found to have flash rates as high as 400 fpm with rapid rate increases. Also, signals were present that may lead to rapid rate decreases which could identify the collapse of the updraft and bounded weak echo region.
5. Summary & Conclusions
Greater detail and examination of this event will be available on the actual poster. Also, check out our web site at http://sunmlb.nws.fit.edu.