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1. Narrowband components in two-celled tornado-like vortices generated in a Ward-type simulator

   https://doi.org/10.1016/j.jweia.2021.104767  

   Zuo, Delong; Tang, Zhuo; Zhang, Hui; James, Darryl; Eguchi, Yuzuru (November 2021, Journal of Wind Engineering and Industrial Aerodynamics)
2. From a vortex gas to a vortex crystal in instability-driven two-dimensional turbulence

   https://doi.org/10.1017/jfm.2024.162  

   van_Kan, Adrian; Favier, Benjamin; Julien, Keith; Knobloch, Edgar (April 2024, Journal of Fluid Mechanics)

   We study structure formation in two-dimensional turbulence driven by an external force, interpolating between linear instability forcing and random stirring, subject to nonlinear damping. Using extensive direct numerical simulations, we uncover a rich parameter space featuring four distinct branches of stationary solutions: large-scale vortices, hybrid states with embedded shielded vortices (SVs) of either sign, and two states composed of many similar SVs. Of the latter, the first is a dense vortex gas where all SVs have the same sign and diffuse across the domain. The second is a hexagonal vortex crystal forming from this gas when the linear instability is sufficiently weak. These solutions coexist stably over a wide parameter range. The late-time evolution of the system from small-amplitude initial conditions is nearly self-similar, involving three phases: initial inverse cascade, random nucleation of SVs from turbulence and, once a critical number of vortices is reached, a phase of explosive nucleation of SVs, leading to a statistically stationary state. The vortex gas is continued in the forcing parameter, revealing a sharp transition towards the crystal state as the forcing strength decreases. This transition is analysed in terms of the diffusivity of individual vortices using ideas from statistical physics. The crystal can also decay via an inverse cascade resulting from the breakdown of shielding or insufficient nonlinear damping acting on SVs. Our study highlights the importance of the forcing details in two-dimensional turbulence and reveals the presence of non-trivial SV states in this system, specifically the emergence and melting of a vortex crystal. 

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3. Hollow vortex in a corner

   https://doi.org/10.1017/jfm.2020.966  

   Christopher, T. W.; Llewellyn Smith, Stefan G. (February 2021, Journal of Fluid Mechanics)

   null (Ed.)

   Equilibrium solutions for hollow vortices in straining flow in a corner are obtained by solving a free-boundary problem. Conformal maps from a canonical doubly connected annular domain to the physical plane combining the Schottky–Klein prime function with an appropriate algebraic map lead to a problem similar to Pocklington's propagating hollow dipole. The result is a two-parameter family of solutions depending on the corner angle and on the non-dimensional ratio of strain to circulation. 

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4. Instability of a dusty vortex

   https://doi.org/10.1017/jfm.2022.687  

   Shuai, Shuai; Jeswin Dhas, Darish; Roy, Anubhab; Kasbaoui, M. Houssem (October 2022, Journal of Fluid Mechanics)

   We investigate the effect of inertial particles dispersed in a circular patch of finite radius on the stability of a two-dimensional Rankine vortex in semi-dilute dusty flows. Unlike the particle-free case where no unstable modes exist, we show that the feedback force from the particles triggers a novel instability. The mechanisms driving the instability are characterized using linear stability analysis for weakly inertial particles and further validated against Eulerian–Lagrangian simulations. We show that the particle-laden vortex is always unstable if the mass loading $M>0$ . Surprisingly, even non-inertial particles destabilize the vortex by a mechanism analogous to the centrifugal Rayleigh–Taylor instability in radially stratified vortex with density jump. We identify a critical mass loading above which an eigenmode $$m$$ becomes unstable. This critical mass loading drops to zero as $$m$$ increases. When particles are inertial, modes that fall below the critical mass loading become unstable, whereas modes above it remain unstable but with lower growth rates compared with the non-inertial case. Comparison with Eulerian–Lagrangian simulations shows that growth rates computed from simulations match well the theoretical predictions. Past the linear stage, we observe the emergence of high-wavenumber modes that turn into spiralling arms of concentrated particles emanating out of the core, while regions of particle-free flow are sucked inward. The vorticity field displays a similar pattern which leads to the breakdown of the initial Rankine structure. This novel instability for a dusty vortex highlights how the feedback force from the disperse phase can induce the breakdown of an otherwise resilient vortical structure. 

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5. A leading-edge vortex initiation criteria for large amplitude foil oscillations using a discrete vortex model

   https://doi.org/10.1063/5.0065097  

   Kamrani Fard, Kiana; Ngo, Vickie; Liburdy, James A. (November 2021, Physics of Fluids)