Litcius/Paper detail

Transition to turbulence in hypersonic flow over a compression ramp due to upstream forcing

Shibin Cao, Jiaao Hao, Peixu Guo

2024Journal of Fluid Mechanics7 citationsDOIOpen Access PDF

Abstract

Several transition scenarios are present in a hypersonic compression-ramp flow. In our previous work (Cao et al. , J. Fluid Mech. , vol. 941, 2022, p. A8), a complete transition process induced by the global instability of a compression-ramp flow was revealed. In a globally stable flow, however, the transition to turbulence can be promoted by convective instabilities, which is the focus of this work. The same flow conditions as in our previous work (Mach number 7.7, Reynolds number $8.6\times 10^5$ based on the flat-plate length) are considered here. Owing to a smaller ramp angle, a weakly separated flow forms on the compression ramp, which supports no global instability. Resolvent analysis identifies low-frequency streamwise streaks as the optimal response of base flow to upstream forcing. Local stability analysis reveals Mack's second mode in the boundary layer downstream of reattachment. By introducing random disturbances upstream of separation in direct numerical simulations, we observe breakdown to turbulence downstream of reattachment. Two transition scenarios are revealed, and they are highly dependent on the amplitude of upstream disturbances. For a large amplitude, strong streamwise streaks develop near the reattachment region, which break down to turbulence quickly. However, when the disturbance amplitude is reduced, the second-mode instability dominates the transition to turbulence.

Topics & Concepts

TurbulenceUpstream (networking)MechanicsForcing (mathematics)Hypersonic speedCompression (physics)Materials scienceFlow (mathematics)MeteorologyEnvironmental sciencePhysicsAtmospheric sciencesComputer scienceTelecommunicationsComposite materialFluid Dynamics and Turbulent FlowsComputational Fluid Dynamics and AerodynamicsGas Dynamics and Kinetic Theory