Amplifier and resonator dynamics of a low-Reynolds-number recirculation bubble in a global framework

Marquet, Olivier; Sipp, Denis; Chomaz, Jean‐Marc; Jacquin, Laurent

doi:10.1017/s0022112008000323

Cited by 87 publications

(85 citation statements)

References 29 publications

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“…In such cases, the linear response to perturbations is transient: initial growth of a wave packet in the unstable region is followed by decay as perturbations advect into the downstream stable region of the flow. The connection between transient growth and localized convective instability was noted by Cossu & Chomaz (1997), Chomaz (2005), and Marquet et al (2008). Here we extend the methodology of Blackburn et al (2008) to unsteady flow.…”

Section: Introductionmentioning

confidence: 76%

Convective instability and transient growth in steady and pulsatile stenotic flows

2008

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We show that suitable initial disturbances to steady or long-period pulsatile flows in a straight tube with an axisymmetric 75%-occlusion stenosis can produce very large transient energy growths. The global optimal disturbances to an initially axisymmetric state found by linear analyses are three-dimensional wave packets that produce localized sinuous convective instability in extended shear layers. In pulsatile flow, initial conditions that trigger the largest disturbances are either initiated at, or advect to, the separating shear layer at the stenosis in phase with peak systolic flow. Movies are available with the online version of the paper.

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Section: Introductionmentioning

confidence: 76%

Convective instability and transient growth in steady and pulsatile stenotic flows

2008

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“…Thus, while a local analysis does give insight into the stability of the boundary layer, it has obvious limitations due the finite nature of the actual flow of interest, and has primarily been used to avoid the computational expense of the analysis with physical boundary conditions. 32 Here, the global linear stability analysis is performed via time evolution of the Navier-Stokes equations. First, a steady axisymmetric basic state is computed at some point in parameter space.…”

Section: Linear Stability Of the Basic State: Spiral Wavesmentioning

confidence: 99%

Crossflow instability of finite Bödewadt flows: Transients and spiral waves

et al. 2009

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The flow in an enclosed rotating cylinder with a stationary lower end wall is investigated numerically. For fast rotation rates, the flow in the interior is primarily in the azimuthal direction, with an angular momentum distribution very close to that corresponding to solid-body rotation for about the inner-half radius. The differential rotation sets up a large-scale circulation that is primarily present in the boundary layers on the rotating top and sidewalls and the stationary bottom wall, with a very weak effusive component throughout the bulk interior providing a matching between the boundary layer flows on the top and bottom. The top end wall boundary layer has a profile that very closely matches the von Kármán solution for a rotating disk boundary layer; it is stable and very robust to finite disturbances for all rotation rates considered. The boundary layer on the stationary bottom end wall has a profile that agrees with the Bödewadt solution for a stationary disk with an ambient flow in solid-body rotation. This boundary layer is not robust, suffering crossflow instability to multiarmed spiral waves via a supercritical Hopf bifurcation, as well as being susceptible to axisymmetric circular waves that travel radially inward where the boundary layer profile is most inflectional. In the absence of any external forcing, the circular waves are transitory, but low amplitude forcing can sustain them indefinitely, whereas the spiral waves are essentially unaffected by the external forcing.

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“…Passive strategies have been used also for reducing the growth of Tollmienn-Schlichting (TS) waves in boundary-layer flows: by placing small cylindrical devices at the wall, the growth rate of TS waves can be reduced and transition due to their asymptotical growth can be delayed (see Fransson et al (2006); Shahinfar et al (2012)). However, in the presence of large environmental disturbances, the boundary-layer presents a very different dynamics, since it behaves like a noise amplifier (for instance, see Marquet et al (2008a); Alizard et al (2009)). Noise amplifiers cannot self-sustain oscillations in the absence of an external disturbance source, but they can strongly amplify a broad range of frequencies and spatial scales.…”

Section: Introductionmentioning

confidence: 99%

Nonlinear control of unsteady finite-amplitude perturbations in the Blasius boundary-layer flow

2013

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is an open access repository that collects the work of Arts et Métiers ParisTech researchers and makes it freely available over the web where possible. 1Nonlinear control of unsteady finite-amplitude perturbations in the Blasius boundary-layer flow The present work provides an optimal control strategy, based on the nonlinear NavierStokes equations, aiming at hampering the rapid growth of unsteady finite-amplitude perturbations in a Blasius boundary-layer flow. A variational procedure is used to find the blowing and suction control law at the wall providing the maximum damping of the energy of a given perturbation at a given target time, with the final aim of leading the flow back to the laminar state. Two optimally-growing finite-amplitude initial perturbations capable of leading very rapidly to transition have been used to initialize the flow. The nonlinear control procedure has been found able to drive such perturbations back to the laminar state, provided that the target time of the minimisation and the region in which the blowing and suction is applied have been suitably chosen. On the other hand, an equivalent control procedure based on the linearized Navier-Stokes equations has been found much less effective, being not able to lead the flow to the laminar state when finite-amplitude disturbances are considered. Regions of strong sensitivity to blowing and suction have been also identified for the given initial perturbations: when the control is actuated in such regions, laminarization is observed also for a shorter extent of the actuation region. The nonlinear optimal blowing and suction law consists of alternated wall-normal velocity perturbations, which appear to modify the core flow structures by means of two distinct mechanisms: i) a wall-normal velocity-compensation at small times; ii) a rotationcounterbalancing effect al larger times. Similar control laws have been observed for different target times, values of the cost parameter, and streamwise extents of the blowing and suction zone, meaning that these two mechanisms are robust features of the optimal control strategy, provided that the nonlinear effects are taken into account.

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Amplifier and resonator dynamics of a low-Reynolds-number recirculation bubble in a global framework

Cited by 87 publications

References 29 publications

Convective instability and transient growth in steady and pulsatile stenotic flows

Convective instability and transient growth in steady and pulsatile stenotic flows

Crossflow instability of finite Bödewadt flows: Transients and spiral waves

Nonlinear control of unsteady finite-amplitude perturbations in the Blasius boundary-layer flow

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