Editorial Type:
Article
Article Type:
Research Article

Simulated Tornadic Vortex Signatures of Tornado-Like Vortices Having One- and Two-Celled Structures

Vincent T. Wood National Severe Storms Laboratory, NOAA/OAR, Norman, Oklahoma

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Rodger A. Brown National Severe Storms Laboratory, NOAA/OAR, Norman, Oklahoma

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Print Publication:
01 Nov 2011
DOI:
https://doi.org/10.1175/JAMC-D-11-0118.1
Page(s):
2338–2342
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Abstract

A tornadic vortex signature (TVS) is a degraded Doppler velocity signature that occurs when the tangential velocity core region of a tornado is smaller than the effective beamwidth of a sampling Doppler radar. Early Doppler radar simulations, which used a uniform reflectivity distribution across an idealized Rankine vortex, showed that the extreme Doppler velocity peaks of a TVS profile are separated by approximately one beamwidth. The simulations also indicated that neither the size nor the strength of the tornado is recoverable from a TVS. The current study was undertaken to investigate how the TVS might change if vortices having more realistic tangential velocity profiles were considered. The one-celled (axial updraft only) Burgers–Rott vortex model and the two-celled (annular updraft with axial downdraft) Sullivan vortex model were selected. Results of the simulations show that the TVS peaks still are separated by approximately one beamwidth—signifying that the TVS not only is unaffected by the size or strength of a tornado but also is unaffected by whether the tornado structure consists of one or two cells.

Corresponding author address: Vincent T. Wood, 120 David L. Boren Blvd., Rm. 3921, Norman, OK 73072-7323. E-mail: vincent.wood@noaa.gov

Abstract

A tornadic vortex signature (TVS) is a degraded Doppler velocity signature that occurs when the tangential velocity core region of a tornado is smaller than the effective beamwidth of a sampling Doppler radar. Early Doppler radar simulations, which used a uniform reflectivity distribution across an idealized Rankine vortex, showed that the extreme Doppler velocity peaks of a TVS profile are separated by approximately one beamwidth. The simulations also indicated that neither the size nor the strength of the tornado is recoverable from a TVS. The current study was undertaken to investigate how the TVS might change if vortices having more realistic tangential velocity profiles were considered. The one-celled (axial updraft only) Burgers–Rott vortex model and the two-celled (annular updraft with axial downdraft) Sullivan vortex model were selected. Results of the simulations show that the TVS peaks still are separated by approximately one beamwidth—signifying that the TVS not only is unaffected by the size or strength of a tornado but also is unaffected by whether the tornado structure consists of one or two cells.

Corresponding author address: Vincent T. Wood, 120 David L. Boren Blvd., Rm. 3921, Norman, OK 73072-7323. E-mail: vincent.wood@noaa.gov
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Journal of Applied Meteorology and Climatology

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