Directed percolation and puff jamming near the transition to pipe turbulence
Lemoult GM, Vasudevan M, Shih HY, Linga G, Mathiesen J, Goldenfeld N, Hof B. 2024. Directed percolation and puff jamming near the transition to pipe turbulence. Nature Physics.
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Journal Article
| Epub ahead of print
| English
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Author
Lemoult, Grégoire MISTA;
Vasudevan, MukundISTA;
Shih, Hong Yan;
Linga, Gaute;
Mathiesen, Joachim;
Goldenfeld, Nigel;
Hof, BjörnISTA
Corresponding author has ISTA affiliation
Department
Abstract
The onset of turbulence in pipe flow has defied detailed understanding ever since the first observations of the spatially heterogeneous nature of the transition. Recent theoretical studies and experiments in simpler, shear-driven flows suggest that the onset of turbulence is a directed-percolation non-equilibrium phase transition, but whether these findings are generic and also apply to open or pressure-driven flows is unknown. In pipe flow, the extremely long time scales near the transition make direct observations of critical behaviour virtually impossible. Here we find a technical solution to that limitation and show that the universality class of the transition is directed percolation, from which a jammed phase of puffs emerges above the critical point. Our method is to experimentally characterize all pairwise interactions between localized patches of turbulence puffs and use these interactions as input for renormalization group and computer simulations of minimal models that extrapolate to long length and time scales. The strong interactions in the jamming regime enable us to explicitly measure the turbulent fraction and confirm model predictions. Our work shows that directed-percolation scaling applies beyond simple closed shear flows and underscores how statistical mechanics can lead to profound, quantitative and predictive insights on turbulent flows and their phases.
Publishing Year
Date Published
2024-05-27
Journal Title
Nature Physics
Publisher
Springer Nature
Acknowledgement
We gratefully acknowledge the assistance of J. M. Lopez with DNSs at an early stage of this work. This work was partially supported by two grants from the Simons Foundation (grant nos. 662985 (N.G.) and 662960 (B.H.)) and by Ministry of Science and Technology, Taiwan (grant nos. MOST 109-2112-M-001-017-MY3 and MOST 111-2112-M-001-027-MY3 (H.-Y.S.)). Part of this work was performed using computing resources of CRIANN (Normandy, France).
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Cite this
Lemoult GM, Vasudevan M, Shih HY, et al. Directed percolation and puff jamming near the transition to pipe turbulence. Nature Physics. 2024. doi:10.1038/s41567-024-02513-0
Lemoult, G. M., Vasudevan, M., Shih, H. Y., Linga, G., Mathiesen, J., Goldenfeld, N., & Hof, B. (2024). Directed percolation and puff jamming near the transition to pipe turbulence. Nature Physics. Springer Nature. https://doi.org/10.1038/s41567-024-02513-0
Lemoult, Grégoire M, Mukund Vasudevan, Hong Yan Shih, Gaute Linga, Joachim Mathiesen, Nigel Goldenfeld, and Björn Hof. “Directed Percolation and Puff Jamming near the Transition to Pipe Turbulence.” Nature Physics. Springer Nature, 2024. https://doi.org/10.1038/s41567-024-02513-0.
G. M. Lemoult et al., “Directed percolation and puff jamming near the transition to pipe turbulence,” Nature Physics. Springer Nature, 2024.
Lemoult GM, Vasudevan M, Shih HY, Linga G, Mathiesen J, Goldenfeld N, Hof B. 2024. Directed percolation and puff jamming near the transition to pipe turbulence. Nature Physics.
Lemoult, Grégoire M., et al. “Directed Percolation and Puff Jamming near the Transition to Pipe Turbulence.” Nature Physics, Springer Nature, 2024, doi:10.1038/s41567-024-02513-0.