Exploring Tornadic Debris Signature Hypotheses Using Radar Simulations and Large-Eddy Simulations

Cross, Rachael N.; Bodine, David J.; Palmer, Robert D.; Griffin, Casey; Cheong, Boonleng; Torres, Sebastian; Fulton, Caleb; Lujan, Javier; Maruyama, Takashi

doi:10.1175/jtech-d-22-0141.1

i

Exploring Tornadic Debris Signature Hypotheses Using Radar Simulations and Large-Eddy Simulations

2023
By Cross, Rachael N. ; Bodine, David J. ; Palmer, Robert D. ; ...

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Journal Title:

Journal of Atmospheric and Oceanic Technology
Personal Author:

Cross, Rachael N. ; Bodine, David J. ; Palmer, Robert D. ; Griffin, Casey ; Cheong, Boonleng ; Torres, Sebastian ; Fulton, Caleb ; Lujan, Javier ; Maruyama, Takashi
NOAA Program & Office:

OAR (Oceanic and Atmospheric Research) ; CIWRO (Cooperative Institute for Severe and High-Impact Weather Research and Operations) ; NSSL (National Severe Storms Laboratory)
Description:

When a tornado lofts debris to the height of the radar beam, a signature known as the tornadic debris signature (TDS) can sometimes be observed on radar. The TDS is a useful signature for operational forecasters because it can confirm the presence of a tornado and provide information about the amount of damage occurring. Since real-time estimates of tornadic intensity do not have a high degree of accuracy, past studies have hypothesized that the TDS could also be an indicator of the strength of a tornado. However, few studies have related the tornadic wind field to TDS characteristics because of the difficulty of obtaining accurate, three-dimensional wind data in tornadoes from radar data. With this in mind, the goals of this study are twofold: 1) to investigate the relationships between polarimetric characteristics of TDSs and the three-dimensional tornadic winds, and 2) to define relationships between polarimetric radar variables and debris characteristics. Simulations are performed using a dual-polarization radar simulator called SimRadar; large-eddy simulations (LESs) of tornadoes; and a single-volume, -matrix-based emulator. Results show that for all simulated debris types increases in horizontal and vertical wind speeds are related to decreases in correlation coefficient and increases in TDS area and height and that, conversely, decreases in horizontal and vertical wind speeds are related to increases in correlation coefficient and decreases in TDS area and height. However, the range of correlation coefficient values varies with debris type, indicating that TDSs that are composed of similar debris types can appear remarkably different on radar in comparison with a TDS with diverse scatterers. Such findings confirm past observational hypotheses and can aid operational forecasters in tornado detection and potentially the categorization of damage severity using radar data.
Keywords:

Atmospheric Science Ocean Engineering
Source:

Journal of Atmospheric and Oceanic Technology, 40(10), 1199-1219
DOI:

https://doi.org/10.1175/jtech-d-22-0141.1
ISSN:

0739-0572 ; 1520-0426
Publisher:

American Meteorological Society
Document Type:

Journal Article
Rights Information:

Other
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Library
Main Document Checksum:

urn:sha256:1a1bef1e6fd5c5da095b5b5be123b9ab08fc1f942a09b3a1f7328aa5e6d0cad1
Download URL:

https://repository.library.noaa.gov/view/noaa/60241/noaa_60241_DS1.pdf
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[PDF - 61.65 MB ]

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