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Your search keyword '"Ermanyuk, E. V."' showing total 37 results
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37 results on '"Ermanyuk, E. V."'

1. Scale effects in internal wave attractors

Author

Brouzet, C., Sibgatullin, I. N., Ermanyuk, E. V., Joubaud, S., and Dauxois, T.

Subjects
Physics - Fluid Dynamics
Abstract

As a necessary preliminary step toward geophysically significant extrapolations, we study the scale effects in internal wave attractors in the linear and nonlinear regimes. We use two geometrically similar experimental set-ups, scaled to factor 3, and numerical simulations (a spectral element method, based on the Nek5000 open solver) for a range of parameters that is typically accessible in laboratory. In the linear regime, we recover the classical viscous scaling for the beam width, which is not affected by variations of the amplitude of the input perturbation. In the nonlinear regime, we show that the scaling of the width-to-length ratio of the attractor branches is intimately related with the energy cascade from large-scale energy input to dissipation. We present results for the wavelength, amplitude and width of the beam as a function of time and as a function of the amplitude of the forcing.

Published
2018
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2. Internal Wave Attractors in 3D Geometries : trapping by oblique reflection

Author

Pillet, G., Ermanyuk, E. V., Maas, L. R. M., Sibgatullin, I. N., and Dauxois, T.

Subjects
Physics - Fluid Dynamics
Abstract

We study experimentally the propagation of internal waves in two different three-dimensional (3D) geometries, with a special emphasis on the refractive focusing due to the 3D reflection of obliquely incident internal waves on a slope. Both studies are initiated by ray tracing calculations to determine the appropriate experimental parameters. First, we consider a 3D geometry, the classical set-up to get simple, 2D parallelogram-shaped attractors in which waves are forced in a direction perpendicular to a sloping bottom. Here, however, the forcing is of reduced extent in along-slope, transverse direction. We show how the refractive focusing mechanism explains the formation of attractors over the whole width of the tank, even away from the forcing region. Direct numerical simulations confirm the dynamics,emphasize the role of boundary conditions and reveal the phase shifting in the transversal direction. Second, we consider a long and narrow tank having an inclined bottom, to simply reproduce a canal. In this case, the energy is injected in a direction parallel to the slope. Interestingly, the wave energy ends up forming 2D internal wave attractors in planes that are transverse to the initial propagation direction. This focusing mechanism prevents indefinite transmission of most of the internal wave energy along the canal.

Published
2018
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3. Added mass: a complex face of tidal conversion

Author

Brouzet, C., Ermanyuk, E. V., Moulin, M., Pillet, G., and Dauxois, T.

Subjects
Physics - Fluid Dynamics
Abstract

This paper revisits the problem of tidal conversion at a ridge in a uniformly stratified fluid of limited depth using measurements of complex-valued added mass. When the height of a sub-marine ridge is non negligible with respect to the depth of the water, the tidal conversion can be enhanced in the supercritical regime or reduced in the subcritical regime with respect to the large depth situation. Tidal conversion can even be null for some specific cases. Here, we study experimentally the influence of finite depth on the added mass coefficients for three diffierent ridge shapes. We first show that at low forcing frequency the tidal conversion is weakly enhanced by shallow depth for a semi-circular ridge. In addition, added mass coefficients measured for a vertical ridge show strong similarities with the ones obtained for the semi-circular ridge. Nevertheless, the enhancement of the tidal conversion at low forcing frequency for the vertical ridge has not been observed, in contrast with its supercritical shape. Finally, we provide the experimental evidence of a lack of tidal conversion due to the specific shape of a ridge for certain depth and frequency tuning.

Published
2018
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4. Internal wave attractors: different scenarios of instability

Author

Brouzet, Christophe, Ermanyuk, E. V., Joubaud, Sylvain, Pillet, Grimaud, and Dauxois, Thierry

Subjects
Physics - Fluid Dynamics
Abstract

This paper presents an experimental study of different instability scenarios in a parallelogram-shaped internal wave attractor in a trapezoidal domain filled with a uniformly stratified fluid. Energy is injected into the system via the oscillatory motion of a vertical wall of the trapezoidal domain. Whole-field velocity measurements are performed with the conventional PIV technique. In the linear regime, the total kinetic energyof the fluid system is used to quantify the strength of attractors as a function of coordinates in the parameter spacedefining their zone of existence, the so-called Arnold tongue. In the nonlinear regime, the choice of the operational point in the Arnold tongue is shown to have a significant impact on the scenario of the onset of triadic instability, most notably on the influence of confinement on secondary waves. The onset of triadic resonance instability may occur as a spatially localized event similar to Scolan, Ermanyuk and Dauxois (2013) in the case of strong focusing or in form of growing normal modes as in McEwan (1971) for the limiting case of rectangular domain. In the present paper, we describe also a new intermediate scenario for the case of weak focusing. We explore the long-term behaviour of cascades of triadic instabilities in wave attractors and show a persistent trend toward formation of standing-wave patterns corresponding to some discrete peaks of the frequency spectrum. At sufficiently high level of energy injection the system exhibits a "mixing box" regime which has certain qualitatively universal properties regardless to the choiceof the operating point in the Arnold tongue. In particular, for this regime, we observe a statisticsof events with high horizontal vorticity, which serve as kinematic indicators of mixing.

Published
2017
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5. Internal wave attractors examined using laboratory experiments and 3D numerical simulations

Author

Brouzet, Christophe, Sibgatullin, Ilias, Scolan, H, Ermanyuk, E. V., and Dauxois, Thierry

Subjects
Physics - Fluid Dynamics
Abstract

In the present paper, we combine numerical and experimental approaches to study the dynamics of stable and unstable internal wave attractors. The problem is considered in a classic trapezoidal setup filled with a uniformly stratified fluid. Energy is injected into the system at global scale by the small-amplitude motion of a vertical wall. Wave motion in the test tank is measured with the help of conventional synthetic schlieren and PIV techniques. The numerical setup closely reproduces the experimental one in terms of geometry and the operational range of the Reynolds and Schmidt numbers. The spectral element method is used as a numerical tool to simulate the nonlinear dynamics of a viscous salt-stratified fluid. We show that the results of three-dimensional calculations are in excellent qualitative and quantitative agreement with the experimental data, including the spatial and temporal parameters of the secondary waves produced by triadic resonance instability. Further, we explore experimentally and numerically the effect of lateral walls on secondary currents and spanwise distribution of velocity amplitudes in the wave beams. Finally, we test the assumption of a bidimensional flow and estimate the error made in synthetic schlieren measurements due to this assumption.

Published
2016
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8. Non-linear fate of internal wave attractors

Author

Scolan, Hélène, Ermanyuk, E. V., and Dauxois, Thierry

Subjects
Nonlinear Sciences - Pattern Formation and Solitons, Physics - Atmospheric and Oceanic Physics, Physics - Fluid Dynamics
Abstract

We present a laboratory study on the instability of internal wave attractors in a trapezoidal fluid domain filled with uniformly stratified fluid. Energy is injected into the system via standing-wave-type motion of a vertical wall. Attractors are found to be destroyed by parametric subharmonic instability (PSI) via a triadic resonance which is shown to provide a very efficient energy pathway from long to short length scales. This study provides an explanation why attractors may be difficult or impossible to observe in natural systems subject to large amplitude forcing.

Published
2013
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