Simulated Supercells in Nontornadic and Tornadic VORTEX2 Environments

Coffer, Brice E.; Parker, Matthew D.

doi:10.1175/mwr-d-16-0226.1

Cited by 82 publications

(37 citation statements)

References 77 publications

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“…The increase in the degree of organization of the LFCB results in the formation of meridionally-oriented "vertical vorticity rivers" [35,36], which first appear at the base of downdrafts northwest of the low-level circulation (Figure 2d). These features, along with enhanced vertical vorticity in an RFD internal boundary, are thought to be the primary storm-scale sources of vertical vorticity to the developing low-level rotation in other simulations in the literature [35][36][37][38]. At 11,888.775 s, the first tornado forms at the tip of the hook as seen in the vertical vorticity field (Figure 2d, Figure 3a, and Figure 4a).…”

Section: Simulated Storm Overviewmentioning

confidence: 68%

Horizontal Vortex Tubes near a Simulated Tornado: Three-Dimensional Structure and Kinematics

et al. 2019

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Supercell thunderstorms can produce a wide spectrum of vortical structures, ranging from midlevel mesocyclones to small-scale suction vortices within tornadoes. A less documented class of vortices are horizontally-oriented vortex tubes near and/or wrapping about tornadoes, that are observed either visually or in high-resolution Doppler radar data. In this study, an idealized numerical simulation of a tornadic supercell at 100 m grid spacing is used to analyze the three-dimensional (3D) structure and kinematics of horizontal vortices (HVs) that interact with a simulated tornado. Visualizations based on direct volume rendering aided by visual observations of HVs in a real tornado reveal the existence of a complex distribution of 3D vortex tubes surrounding the tornadic flow throughout the simulation. A distinct class of HVs originates in two key regions at the surface: around the base of the tornado and in the rear-flank downdraft (RFD) outflow and are believed to have been generated via surface friction in regions of strong horizontal near-surface wind. HVs around the tornado are produced in the tornado outer circulation and rise abruptly in its periphery, assuming a variety of complex shapes, while HVs to the south-southeast of the tornado, within the RFD outflow, ascend gradually in the updraft.

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Section: Simulated Storm Overviewmentioning

confidence: 68%

Horizontal Vortex Tubes near a Simulated Tornado: Three-Dimensional Structure and Kinematics

et al. 2019

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“…Previous studies (i.e., Wicker 1996;Miller, 2006;Esterheld and Giuliano 2008;Nowotarski and Jensen 2013;Coffer and Parker 2017) have identified this shear profile as being unfavorable for tornadogenesis, suggesting that such a profile (with its weaker storm-relative winds opposing the gust front) results in outflow dominated storms in which low-level circulation is advected ahead of the primary midlevel updraft/mesocyclone. However, the three simulations containing the α = 0° wind profile correspond to the three highest near-surface vorticity maxima of all the simulations performed.…”

Section: Additional Considerationsmentioning

confidence: 90%

The Influence of Lifting Condensation Level on Low-Level Outflow and Rotation in Simulated Supercell Thunderstorms

Brown

Nowotarski

2019

Journal of the Atmospheric Sciences

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This paper reports on results of idealized numerical simulations testing the influence of low-level humidity, and thus lifting condensation level (LCL), on the morphology and evolution of low-level rotation in supercell thunderstorms. Previous studies have shown that the LCL can influence outflow buoyancy, which can in turn affect generation and stretching of near-surface vertical vorticity. A less explored hypothesis is tested: that the LCL affects the relative positioning of near-surface circulation and the overlying mesocyclone, thus influencing the dynamic lifting and intensification of near-surface vertical vorticity. To test this hypothesis, a set of three base-state thermodynamic profiles with varying LCLs are implemented and compared over a variety of low-level wind profiles. The thermodynamic properties of the simulations are sensitive to variations in the LCL, with higher LCLs contributing to more negatively buoyant cold pools. These outflow characteristics allow for a more forward propagation of near-surface circulation relative to the midlevel mesocyclone. When the mid- and low-level mesocyclones become aligned with appreciable near-surface circulation, favorable dynamic updraft forcing is able to stretch and intensify this rotation. The strength of the vertical vorticity generated ultimately depends on other interrelated factors, including the amount of near-surface circulation generated within the cold pool and the buoyancy of storm outflow. However, these simulations suggest that mesocyclone alignment with near-surface circulation is modulated by the ambient LCL, and is a necessary condition for the strengthening of near-surface vertical vorticity. This alignment is also sensitive to the low-level wind profile, meaning that the LCL most favorable for the formation of intense vorticity may change based on ambient low-level shear properties.

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“…In [1], we find this statement about including surface drag in a storm model: "Our philosophy is that the inclusion of modest surface drag represents a more physically consistent bottom boundary condition for tornadogenesis than does the habitually employed free-slip assumption." Several other recent storm modeling efforts have investigated surface drag in storm evolution and tornadogenesis [2][3][4].…”

Section: Introductionmentioning

confidence: 90%

“…As used here, semi-slip refers to the simplest application that we see atmospheric modeling, such as in [1,3,10]. It could also be called bulk drag.…”

Section: Introductionmentioning

confidence: 99%

Axisymmetric Tornado Simulations with a Semi-Slip Boundary

Fiedler

2017

Fluids

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The structure of natural tornadoes and simulated analogs are sensitive to the lower boundary condition for friction. Three-dimensional numerical simulations of storms require a choice for turbulence parameterizations and resolution of wind near the lower boundary. This article explores some of the consequences of choices of a surface drag coefficient on the structure of a mature simulated tornado, using a conventional axisymmetric model. The surface drag parameterization is explored over the range of the semi-slip condition, including the extremes of no-slip and free-slip. A moderate semi-slip condition allows for an extreme pressure deficit, but without the unrealistic vortex breakdown of the no-slip condition.

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Simulated Supercells in Nontornadic and Tornadic VORTEX2 Environments

Cited by 82 publications

References 77 publications

Horizontal Vortex Tubes near a Simulated Tornado: Three-Dimensional Structure and Kinematics

Horizontal Vortex Tubes near a Simulated Tornado: Three-Dimensional Structure and Kinematics

The Influence of Lifting Condensation Level on Low-Level Outflow and Rotation in Simulated Supercell Thunderstorms

Axisymmetric Tornado Simulations with a Semi-Slip Boundary

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