Perturbation avalanche in bypass transition in flow around flat plate by Xuerui Mao (Nottingham)

Duration: 29 mins 25 secs

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Perturbation avalanche in bypass transition in flow around flat plate by Xuerui Mao (Nottingham)'s image

Description:	Talk given by Dr Xuerui Mao (University of Nottingham) at Aerodynamics and Flight Mechanics group, University of Southampton on 3 March 2021, as part of the Southampton/AFM seminar series.


Created:	2021-03-16 10:19
Collection:	UKFN_Southampton_AFM
Publisher:	University of Cambridge
Copyright:	Dr Xuerui Mao
Language:	eng (English)


Abstract:	The optimal route from free-stream perturbations to bypass transition in a flat plate boundary layer is found by computing the nonlinear optimal inflow perturbation. This study fills the gap between secondary instability of velocity streaks and transition, and reveals that the transition is not the consequence of the saturation of the most unstable secondary instability as widely supposed, but of the interaction of multiple secondary modes, whose phase mismatch induces strong shears leading to a tertiary instability. The optimal route illustrates that free-stream perturbation components gradually enter the boundary layer and contribute to transition successively: the steady (and low-frequency) inflow perturbations induce near-wall velocity streaks; the sinusoidal meandering motion of streaks triggered by high-frequency perturbations generates helical vortex filaments; the filaments then undergo tertiary instability associated with higher-frequency perturbations leading to an avalanche of breakdown into a tangle of numerous finer-scale vortices and thence to turbulence.

Abstract:

The optimal route from free-stream perturbations to bypass transition in a flat plate boundary layer is found by computing the nonlinear optimal inflow perturbation. This study fills the gap between secondary instability of velocity streaks and transition, and reveals that the transition is not the consequence of the saturation of the most unstable secondary instability as widely supposed, but of the interaction of multiple secondary modes, whose phase mismatch induces strong shears leading to a tertiary instability. The optimal route illustrates that free-stream perturbation components gradually enter the boundary layer and contribute to transition successively: the steady (and low-frequency) inflow perturbations induce near-wall velocity streaks; the sinusoidal meandering motion of streaks triggered by high-frequency perturbations generates helical vortex filaments; the filaments then undergo tertiary instability associated with higher-frequency perturbations leading to an avalanche of breakdown into a tangle of numerous finer-scale vortices and thence to turbulence.

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