Parametric resonance in the dynamics of an elliptic vortex in a periodically strained environment

Mapping Intimacies ◽

10.5194/npg-2016-51 ◽

2016 ◽

Author(s):

Konstantin V. Koshel ◽

Eugene A. Ryzhov

Keyword(s):

Parametric Instability ◽

Vortex Motion ◽

Nonlinear Effects ◽

Space Region ◽

Linear Deformation ◽

Stationary Vortex ◽

Strain Axis ◽

Secondary Zone ◽

Perturbation Parameters ◽

Effective Growth

Abstract. The model of an elliptic vortex evolving in a periodically strained background flow is studied in order to establish the possible unbounded regimes. Depending on the parameters of the exterior flow, there are three classical regimes of the elliptic vortex motion under constant linear deformation: (i) rotation, (ii) nutation, and (iii) infinite elongation. The phase portrait for the vortex dynamics features critical points, which correspond to the stationary vortex not changing its form and orientation. We demonstrate that, given superimposed periodic oscillations to the exterior deformation, the phase space region corresponding to the elliptic critical point experiences parametric instability leading to locally unbounded dynamics of the vortex. This dynamics manifests itself as the vortex nutates along the strain axis while continuously elongating. This motion continues until nonlinear effects intervene near the region associated with the steady-state separatrix. Next, we show that for specific values of the perturbation parameters, the parametric instability is effectively suppressed by nonlinearity in the primal parametric instability zone. The secondary zone of the parametric instability, on the contrary, produces an effective growth of the vortex's aspect ratio.

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Parametric resonance in the dynamics of an elliptic vortex in a periodically strained environment

Nonlinear Processes in Geophysics ◽

10.5194/npg-24-1-2017 ◽

2017 ◽

Vol 24 (1) ◽

pp. 1-8 ◽

Cited By ~ 5

Author(s):

Konstantin V. Koshel ◽

Eugene A. Ryzhov

Keyword(s):

Parametric Instability ◽

Vortex Motion ◽

Nonlinear Effects ◽

Space Region ◽

Linear Deformation ◽

Stationary Vortex ◽

Strain Axis ◽

Secondary Zone ◽

Perturbation Parameters ◽

Effective Growth

Abstract. The model of an elliptic vortex evolving in a periodically strained background flow is studied in order to establish the possible unbounded regimes. Depending on the parameters of the exterior flow, there are three classical regimes of the elliptic vortex motion under constant linear deformation: (i) rotation, (ii) nutation, and (iii) infinite elongation. The phase portrait for the vortex dynamics features critical points which correspond to the stationary vortex not changing its form and orientation. We demonstrate that, given superimposed periodic oscillations to the exterior deformation, the phase space region corresponding to the elliptic critical point experiences parametric instability leading to locally unbounded dynamics of the vortex. This dynamics manifests itself as the vortex nutates along the strain axis while continuously elongating. This motion continues until nonlinear effects intervene near the region associated with the steady-state separatrix. Next, we show that, for specific values of the perturbation parameters, the parametric instability is effectively suppressed by nonlinearity in the primal parametric instability zone. The secondary zone of the parametric instability, on the contrary, produces an effective growth of the vortex's aspect ratio.

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Dynamic Instability in Quartering Seas—Part III: Nonlinear Effects on Periodic Motions

Journal of Ship Research ◽

10.5957/jsr.1997.41.3.210 ◽

1997 ◽

Vol 41 (03) ◽

pp. 210-223 ◽

Cited By ~ 1

Author(s):

K. J. Spyrou

Keyword(s):

Periodic Motion ◽

Horizontal Plane ◽

Dynamic Instability ◽

Parametric Instability ◽

Nonlinear Effects ◽

Ship Motions ◽

Nonlinear Phenomena ◽

Specific Sequence ◽

The Stability ◽

Two Stages

The loss of stability of the horizontal-plane periodic motion of a steered ship in waves is investigated. In earlier reports we referred to the possibility of a broaching mechanism that will be intrinsic to the periodic mode, whereby there will exist no need for the ship to go through the surf-riding stage. However, about this point the discussion was essentially conjectural. In order to provide substance we present here a theoretical approach that is organized in two stages: Initially, we demonstrate the existence of a mechanism of parametric instability of yaw on the basis of a rudimentary, single-degree model of maneuvering motion in waves. Then, with a more elaborate model, we identify the underlying nonlinear phenomena that govern the large-amplitude horizontal ship motions, considering the ship as a multi-degree, nonlinear oscillator. Our analysis brings to light a very specific sequence of phenomena leading to cumulative broaching that involves a change in the stability of the ordinary periodic motion on the horizontal plane, a transition towards subharmonic response and, ultimately, a sudden jump to resonance. Possible means for controlling the onset of such undesirable behavior are also investigated.

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Исследование связанной динамики магнитных вихрей в трехслойном проводящем наноцилиндре

Физика твердого тела ◽

10.21883/ftt.2018.06.45974.22m ◽

2018 ◽

Vol 60 (6) ◽

pp. 1045

Author(s):

С.В. Степанов ◽

А.Е. Екомасов ◽

К.А. Звездин ◽

Е.Г. Екомасов

Keyword(s):

Magnetic Field ◽

External Magnetic Field ◽

Vortex Motion ◽

Numerical Data ◽

Sample Plane ◽

Current Dependence ◽

Magnetic Vortices ◽

Lifshitz Equation ◽

Spin Polarized ◽

Stationary Vortex

AbstractSolving numerically the generalized Landau–Lifshitz equation, we have carried out the micromagnetic investigation of the dynamics of two dipole-coupled magnetic vortices in a trilayer nanocolumn under the action of the external magnetic field directed perpendicular to the sample plane and spin-polarized electric field. The possible existence of different regimes of vortex motion, depending on the polarized current, is demonstrated. The current dependence of the oscillation frequency for the case of stationary dynamics of coupled vortices with the same frequency has been established. The possibility of controlling the frequency of the stationary vortex motion and tuning the control current amplitude by the external magnetic field is shown. Using the analytical method for simplified description of the dynamics of coupled vortices, the current and magnetic-field dependences of the frequency have been obtained, which are qualitatively consistent with the numerical data.

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Parametric instability of a many point-vortex system in a multi-layer flow under linear deformation

Regular and Chaotic Dynamics ◽

10.1134/s1560354716030023 ◽

2016 ◽

Vol 21 (3) ◽

pp. 254-266 ◽

Cited By ~ 5

Author(s):

Eugene A. Ryzhov ◽

Konstantin V. Koshel

Keyword(s):

Parametric Instability ◽

Point Vortex ◽

Vortex System ◽

Linear Deformation ◽

Layer Flow

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Explosive instability of baroclinic waves

Proceedings of the Royal Society of London Series A - Mathematical and Physical Sciences ◽

10.1098/rspa.1984.0103 ◽

1984 ◽

Vol 395 (1809) ◽

pp. 313-339 ◽

Cited By ~ 1

Keyword(s):

Rapid Growth ◽

Parametric Instability ◽

Nonlinear Effects ◽

Threshold Value ◽

Initial Energy ◽

Unstable Wave ◽

Weakly Nonlinear ◽

Explosive Instability ◽

Resonant Interactions ◽

The Waves

Resonant interactions between a marginally unstable wave and one or two pairs of slightly damped waves in a quasi-geostrophic two-layer flow on a beta plane are investigated. It is found that a system of waves that is stable under strictly inviscid conditions is destabilized by slight viscosity provided the initial energy of the participating waves exceeds a certain threshold value. In the linear phase viscosity can trigger parametric instability. When weakly nonlinear interactions are considered viscosity can lead to explosive instability, whereby the amplitudes of the waves grow without bound at a finite time. The unbounded growth is not always halted by increasing the number of participating waves or by considering higher-order nonlinear effects. The phenomenon of explosive instability whose significance lies in the rapid growth of the amplitudes of the waves on the approach to the singularity may explain the rapid growth of certain events of cyclogenesis recently observed.

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