Saved in:
Bibliographic Details
Main Authors: Taniguchi, Nobutaka, Yakeno, Aiko
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.11964
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866914260935770112
author Taniguchi, Nobutaka
Yakeno, Aiko
author_facet Taniguchi, Nobutaka
Yakeno, Aiko
contents This study investigates the minimal seed for laminar-to-turbulent transition in a supersonic boundary layer at $M=3.0$ and $Re=300$ using adjoint-based nonlinear non-modal analysis. While linear theory identifies oblique waves as the optimal disturbances for transient growth, we demonstrate that nonlinear effects fundamentally alter the optimal perturbation structure as the initial amplitude exceeds a critical threshold. Our analysis reveals that the nonlinear optimal perturbation exhibits a distinctive spatial distribution characterized by flattened structures in the outer layer and streamwise vortices near the wall, leading to a more rapid transition compared to the linear counterpart. A key finding is that this nonlinear amplification mechanism remains robust even under wall-cooled conditions ($T_w = 0.6 T_{ad}$), where the disappearance of the generalized inflection point (GIP) suppresses linear instabilities of Mack's first mode. This rapid growth is driven by the nonlinear interaction between two-dimensional planar waves near the wall and staggered vortex patterns in the outer layer, facilitating streak formation through vortex self-induction. Although the late-stage evolution eventually converges to the classical oblique breakdown scenario as characterized by the formation of $Λ$-vortices, the identified nonlinear path significantly reduces the disturbance energy required for transition.
format Preprint
id arxiv_https___arxiv_org_abs_2601_11964
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Minimal seed in supersonic boundary layer at $M=3$
Taniguchi, Nobutaka
Yakeno, Aiko
Fluid Dynamics
This study investigates the minimal seed for laminar-to-turbulent transition in a supersonic boundary layer at $M=3.0$ and $Re=300$ using adjoint-based nonlinear non-modal analysis. While linear theory identifies oblique waves as the optimal disturbances for transient growth, we demonstrate that nonlinear effects fundamentally alter the optimal perturbation structure as the initial amplitude exceeds a critical threshold. Our analysis reveals that the nonlinear optimal perturbation exhibits a distinctive spatial distribution characterized by flattened structures in the outer layer and streamwise vortices near the wall, leading to a more rapid transition compared to the linear counterpart. A key finding is that this nonlinear amplification mechanism remains robust even under wall-cooled conditions ($T_w = 0.6 T_{ad}$), where the disappearance of the generalized inflection point (GIP) suppresses linear instabilities of Mack's first mode. This rapid growth is driven by the nonlinear interaction between two-dimensional planar waves near the wall and staggered vortex patterns in the outer layer, facilitating streak formation through vortex self-induction. Although the late-stage evolution eventually converges to the classical oblique breakdown scenario as characterized by the formation of $Λ$-vortices, the identified nonlinear path significantly reduces the disturbance energy required for transition.
title Minimal seed in supersonic boundary layer at $M=3$
topic Fluid Dynamics
url https://arxiv.org/abs/2601.11964