Stochastic Model for Quasi-One-Dimensional Transitional Turbulence with Streamwise Shear Interactions

Xueying Wang; Hong Yan Shih; Nigel Goldenfeld

doi:10.1103/PhysRevLett.129.034501

Stochastic Model for Quasi-One-Dimensional Transitional Turbulence with Streamwise Shear Interactions

Xueying Wang, Hong Yan Shih, Nigel Goldenfeld

Physics

Research output: Contribution to journal › Article › peer-review

Abstract

The transition to turbulence in wall-bounded shear flows is typically subcritical, with a poorly understood interplay between spatial fluctuations, pattern formation, and stochasticity near the critical Reynolds number. Here, we present a spatially extended stochastic minimal model for the energy budget in transitional pipe flow, which successfully recapitulates the way localized patches of turbulence (puffs) decay, split, and grow, respectively, as the Reynolds number increases through the laminar-turbulent transition. Our approach takes into account the flow geometry, as we demonstrate by extending the model to quasi-one-dimensional Taylor-Couette flow, reproducing the observed directed percolation pattern of turbulent patches in space and time.

Original language	English (US)
Article number	034501
Journal	Physical review letters
Volume	129
Issue number	3
Early online date	Jul 11 2022
DOIs	https://doi.org/10.1103/PhysRevLett.129.034501
State	Published - Jul 15 2022

ASJC Scopus subject areas

General Physics and Astronomy

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10.1103/PhysRevLett.129.034501

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title = "Stochastic Model for Quasi-One-Dimensional Transitional Turbulence with Streamwise Shear Interactions",

abstract = "The transition to turbulence in wall-bounded shear flows is typically subcritical, with a poorly understood interplay between spatial fluctuations, pattern formation, and stochasticity near the critical Reynolds number. Here, we present a spatially extended stochastic minimal model for the energy budget in transitional pipe flow, which successfully recapitulates the way localized patches of turbulence (puffs) decay, split, and grow, respectively, as the Reynolds number increases through the laminar-turbulent transition. Our approach takes into account the flow geometry, as we demonstrate by extending the model to quasi-one-dimensional Taylor-Couette flow, reproducing the observed directed percolation pattern of turbulent patches in space and time.",

author = "Xueying Wang and Shih, \{Hong Yan\} and Nigel Goldenfeld",

note = "We gratefully acknowledge valuable discussions with Dwight Barkley and Bj{\"o}rn Hof. This work was supported by a grant from the Simons Foundation (Grant No. 662985, N. G.) and from the Ministry of Science and Technology, Taiwan (Grant No. MOST 109-2112-M-001-017-MY3).",

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N1 - We gratefully acknowledge valuable discussions with Dwight Barkley and Björn Hof. This work was supported by a grant from the Simons Foundation (Grant No. 662985, N. G.) and from the Ministry of Science and Technology, Taiwan (Grant No. MOST 109-2112-M-001-017-MY3).

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N2 - The transition to turbulence in wall-bounded shear flows is typically subcritical, with a poorly understood interplay between spatial fluctuations, pattern formation, and stochasticity near the critical Reynolds number. Here, we present a spatially extended stochastic minimal model for the energy budget in transitional pipe flow, which successfully recapitulates the way localized patches of turbulence (puffs) decay, split, and grow, respectively, as the Reynolds number increases through the laminar-turbulent transition. Our approach takes into account the flow geometry, as we demonstrate by extending the model to quasi-one-dimensional Taylor-Couette flow, reproducing the observed directed percolation pattern of turbulent patches in space and time.

AB - The transition to turbulence in wall-bounded shear flows is typically subcritical, with a poorly understood interplay between spatial fluctuations, pattern formation, and stochasticity near the critical Reynolds number. Here, we present a spatially extended stochastic minimal model for the energy budget in transitional pipe flow, which successfully recapitulates the way localized patches of turbulence (puffs) decay, split, and grow, respectively, as the Reynolds number increases through the laminar-turbulent transition. Our approach takes into account the flow geometry, as we demonstrate by extending the model to quasi-one-dimensional Taylor-Couette flow, reproducing the observed directed percolation pattern of turbulent patches in space and time.

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Stochastic Model for Quasi-One-Dimensional Transitional Turbulence with Streamwise Shear Interactions

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