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Auteurs principaux: Wu, Xiaohua, Gonzalez, Carlos A., Agrawal, Rahul
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2503.03844
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author Wu, Xiaohua
Gonzalez, Carlos A.
Agrawal, Rahul
author_facet Wu, Xiaohua
Gonzalez, Carlos A.
Agrawal, Rahul
contents We report a comprehensive set of direct numerical simulation benchmarks of bypass transition in the narrow sense with inlet freestream turbulent intensity levels of 0.75%, 1.5%, 2.25%, 3.0%, and 6.0%, respectively. Detailed descriptions of length scales and the rate of viscous dissipation are provided. We ask two key physical questions. First, how do the decay rates and length scales of freestream turbulence over a transitional and turbulent boundary layer compare to those in spatially developing isotropic turbulence without the wall? Second, what bypass mechanisms drive turbulent spot inception at the intermediate rage of freestream turbulence intensity level? We find that the boundary-layer freestream turbulence decay and length scales evolve similarly to their spatially developing isotropic turbulence flow without the wall counterparts. We also present evidence of the coexistence of two turbulent spot inception mechanisms at the inlet FST level of 2.25%: the long low-speed streak primary and secondary instabilities (only in lower inlet FST levels) and the self-amplifying process of oblique vortex filaments interacting with a Delta-shaped low-speed patch underneath (prevailing only in higher inlet FST levels).
format Preprint
id arxiv_https___arxiv_org_abs_2503_03844
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Direct numerical simulation benchmarks for the prediction of boundary layer bypass transition in the narrow sense
Wu, Xiaohua
Gonzalez, Carlos A.
Agrawal, Rahul
Fluid Dynamics
We report a comprehensive set of direct numerical simulation benchmarks of bypass transition in the narrow sense with inlet freestream turbulent intensity levels of 0.75%, 1.5%, 2.25%, 3.0%, and 6.0%, respectively. Detailed descriptions of length scales and the rate of viscous dissipation are provided. We ask two key physical questions. First, how do the decay rates and length scales of freestream turbulence over a transitional and turbulent boundary layer compare to those in spatially developing isotropic turbulence without the wall? Second, what bypass mechanisms drive turbulent spot inception at the intermediate rage of freestream turbulence intensity level? We find that the boundary-layer freestream turbulence decay and length scales evolve similarly to their spatially developing isotropic turbulence flow without the wall counterparts. We also present evidence of the coexistence of two turbulent spot inception mechanisms at the inlet FST level of 2.25%: the long low-speed streak primary and secondary instabilities (only in lower inlet FST levels) and the self-amplifying process of oblique vortex filaments interacting with a Delta-shaped low-speed patch underneath (prevailing only in higher inlet FST levels).
title Direct numerical simulation benchmarks for the prediction of boundary layer bypass transition in the narrow sense
topic Fluid Dynamics
url https://arxiv.org/abs/2503.03844