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Autori principali: Senkardesler, Mert, Karpuzcu, Irmak T., Levin, Deborah A., Theofilis, Vassilis
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2512.11390
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author Senkardesler, Mert
Karpuzcu, Irmak T.
Levin, Deborah A.
Theofilis, Vassilis
author_facet Senkardesler, Mert
Karpuzcu, Irmak T.
Levin, Deborah A.
Theofilis, Vassilis
contents A flat-plate laminar boundary layer is simulated at Mach 6 and unit Reynolds number of 1.1e7 using the Direct Simulation Monte Carlo (DSMC) method to capture and analyze spontaneous second-mode instability growth. Power spectral density (PSD) analysis identifies dominant frequencies of 200-400 kHz, in line with linear stability theory (LST) predictions. Near-wall perturbations remain confined within the unstable regions known from linear theory. Dynamic mode decomposition (DMD) of unsteady flowfield snapshots reveals wave packets of spatially coherent modes having wavelengths and phase speeds characteristic of the acoustic second mode; their growth and decay occur exclusively within LST-predicted unstable bounds. Targeted interaction with these flow instabilities is demonstrated for an acoustic vibrating surface (AVS), where forcing at the unstable frequency of 300 kHz results in amplified waves downstream, while at the stable frequency of 500 kHz AVS-induced disturbances are damped. This further emphasizes the ability of the present kinetic simulations to capture and describe linear perturbations at high Reynolds numbers and suggests that DSMC will be a useful tool for understanding theoretically founded control of laminar-turbulent transition in hypersonic boundary layers.
format Preprint
id arxiv_https___arxiv_org_abs_2512_11390
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A Molecular Gas Dynamics Study of Hypersonic Boundary Layer Second Mack Mode Instabilities
Senkardesler, Mert
Karpuzcu, Irmak T.
Levin, Deborah A.
Theofilis, Vassilis
Fluid Dynamics
A flat-plate laminar boundary layer is simulated at Mach 6 and unit Reynolds number of 1.1e7 using the Direct Simulation Monte Carlo (DSMC) method to capture and analyze spontaneous second-mode instability growth. Power spectral density (PSD) analysis identifies dominant frequencies of 200-400 kHz, in line with linear stability theory (LST) predictions. Near-wall perturbations remain confined within the unstable regions known from linear theory. Dynamic mode decomposition (DMD) of unsteady flowfield snapshots reveals wave packets of spatially coherent modes having wavelengths and phase speeds characteristic of the acoustic second mode; their growth and decay occur exclusively within LST-predicted unstable bounds. Targeted interaction with these flow instabilities is demonstrated for an acoustic vibrating surface (AVS), where forcing at the unstable frequency of 300 kHz results in amplified waves downstream, while at the stable frequency of 500 kHz AVS-induced disturbances are damped. This further emphasizes the ability of the present kinetic simulations to capture and describe linear perturbations at high Reynolds numbers and suggests that DSMC will be a useful tool for understanding theoretically founded control of laminar-turbulent transition in hypersonic boundary layers.
title A Molecular Gas Dynamics Study of Hypersonic Boundary Layer Second Mack Mode Instabilities
topic Fluid Dynamics
url https://arxiv.org/abs/2512.11390