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Earth Observing Laboratory
Field Data Archive

VORTEX-SE_2017: Verification of the Origins of Rotation in Tornadoes EXperiment-Southeast (VORTEX-SE) 2017 Field Campaign

Summary

The Verification of the Origins of Rotation in Tornadoes Experiment Southeast (VORTEX-SE) Is a research program designed to understand how environmental factors characteristic of the southeastern United States affect the formation, intensity, structure, and path of tornadoes in this region. VORTEX-SE is also determining the best methods for communicating forecast uncertainty related to these events to the public, and evaluating public response. In many ways, VORTEX-SE represents a new approach to tornado research in general. Previous VORTEX projects were focused on Great Plains events, which by comparison with tornadoes in the southeastern United States, generally form under somewhat different meteorological conditions, display distinctive tornado climatology, and have dissimilar social elements in terms of tornado preparedness, awareness, and communications.   In examining the distribution of tornadoes and tornado deaths in the U.S., Ashley (2007 Weather and Forecasting) found that the number of killer tornadoes in the southeastern U.S. is disproportionately large when compared to the overall number of tornadoes. Ashley attributed this finding to a "unique juxtaposition of a series of physical and sociological variables," including tornadoes at night, in forested areas, prior to the perceived peak of the "tornado season," at a time of year when storms typically have large forward speeds. The study also identified lack of visibility, relatively inadequate shelter, and larger population density as being issues that increase the vulnerability of residents of the southeastern U.S. VORTEX-SE will be the first severe storms experiment that will have a specific emphasis on addressing the sociological factors that contribute to the relatively large tornado mortality in this region of the country. In addition, it is anticipated that VORTEX-SE will involve a series of field campaigns, such as the one described here, to iteratively improve our understanding of the regional peculiarities in the meteorological conditions and storm processes associated with Southeast tornadoes.

For the 2017 field season (8 March to 8 May 2017) VORTEX-SE has a primary domain in the area of northern Alabama with two subdomains, the Sand Mountain domain over northeastern Alabama and the "Western Domain" that covers northern Alabama to the west of Huntsville.  A number of fixed and mobile facilities from the 2016 field season will also be available for 2017 including the University of Alabama-Huntsville (UAH) Mobile Alabama X-band (MAX) radar, University of Massachusettes X-Pol mobile radar, UAH Mobile Integrated Profiling System (MIPS), UAH Rapidly Deployable Atmospheric Profiling System (RaDAPS), UAH Mobile Doppler Lidar and Sounding system (MoDLS), The NOAA/National Severe Storms Laboratory and University of Oklahoma Collaborative Lower Atmsopheric Mobile Profiling System (CLAMPS), the Texas Tech University Sticknet, several fixed and mobile radiosonde systems, as well as boundary layer supersites at Belle Mina, Culman and the SWIRLL building at UAH.  Additional instrumentation for the 2017 field season includes the NOAA P-3 aircraft and University of Oklahoma SMART-R mobile radars.

Data access

Datasets from this project

Additional information

Field catalog
Related links

Temporal coverage

Begin Date 2017-03-01 00:00:00
End Date 2017-05-08 23:59:59

Spatial coverage


Map data from IBCSO, IBCAO, and Global Topography.

Maximum (North) Latitude: 45.00, Minimum (South) Latitude: 25.00
Minimum (West) Longitude: -95.00, Maximum (East) Longitude: -75.00

NSF

This material is based upon work supported by the NSF National Center for Atmospheric Research, a major facility sponsored by the U.S. National Science Foundation and managed by the University Corporation for Atmospheric Research. Any opinions, findings and conclusions or recommendations expressed in this material do not necessarily reflect the views of the U.S. National Science Foundation.