Formation of turbulent patterns near the onset of transition in plane Couette flow

Duguet, Yohann; Schlatter, Philipp; Henningson, Dan S.

doi:10.1017/s0022112010000297

Cited by 188 publications

(322 citation statements)

References 26 publications

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“…Unlike the PPF, the basic state of PCF has velocities in opposite directions on each channel half, and hence, the perturbations extend in a zigzag style. 25 When the band is long enough, its two ends are close to each other due to the periodic boundary conditions, and the interactions between the large-scale flows around the ITBs cause band breaking as reported in Fig. 2(e).…”

Section: -mentioning

confidence: 85%

“…The mechanism for the growth in the oblique direction is similar to that of PCF, [24][25][26] where the large-scale motions play the key role. At t = 950, a long band is formed (see Fig.…”

Section: -mentioning

confidence: 94%

“…Similarly, a simulation of plane-Couette flow showed that the turbulent fraction did not converge to a statistically steady value at Re = 325. 25 In this letter, we used more samples to study the long-term effect of band interaction on the volume-averaged kinetic energy of the whole flow field. A flow state similar to that depicted in Fig.…”

Section: -mentioning

confidence: 99%

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Turbulent bands in plane-Poiseuille flow at moderate Reynolds numbers

et al. 2015

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In this letter, we show via numerical simulations that the typical flow structures appearing in transitional channel flows at moderate Reynolds numbers are not spots but isolated turbulent bands, which have much longer lifetimes than the spots. Localized perturbations can evolve into isolated turbulent bands by continuously growing obliquely when the Reynolds number is larger than 660. However, interactions with other bands and local perturbations cause band breaking and decay. The competition between the band extension and breaking does not lead to a sustained turbulence until Re becomes larger than about 1000. Above this critical value, the bands split, providing an effective mechanism for turbulence spreading.

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Section: -mentioning

confidence: 85%

“…The mechanism for the growth in the oblique direction is similar to that of PCF, [24][25][26] where the large-scale motions play the key role. At t = 950, a long band is formed (see Fig.…”

Section: -mentioning

confidence: 94%

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Turbulent bands in plane-Poiseuille flow at moderate Reynolds numbers

et al. 2015

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“…The size of the flow domain is very important to capture the necessary phenomena, because of the huge separation of time scales that emerges near the transition. To date, the state-of-the-art was the plane Couette simulations of Duguet, Schlatter & Henningson (2010), conducted in a spatial domain whose [x, y, z] dimensions were [800h, 2h, 356h] where 2h is the gap between the walls, and which lasted O(10 4 ) time units. In contrast, the study of Chantry et al (2017) was in a computational domain of streamwise and spanwise size 2560h × 2560h, and lasted O(10 6 ) time units; thus it was not simply an incremental improvement on the state-of-the-art.…”

Section: Overviewmentioning

confidence: 99%

A statistical mechanical phase transition to turbulence in a model shear flow

Goldenfeld

2017

J. Fluid Mech.

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It is becoming increasingly clear that the strong spatial and temporal fluctuations observed in a narrow Reynolds number regime around the laminar-turbulent transition in shear flows can best be understood using the concepts and techniques from a seemingly unrelated discipline -statistical mechanics. During the last few years, a consensus has begun to emerge that these phenomena reflect an underlying non-equilibrium phase transition exhibited by a model of interacting particles on a crystalline lattice, directed percolation, that seems very far from fluid mechanics. Now, Chantry et al. (J. Fluid Mech., vol. 824, 2017, R1) have developed a truncated-mode computation of a model shear flow, capable of simulating systems far larger and longer than any previous study and have for the first time generated enough statistical data that a high-precision test of theory is feasible. The results broadly confirm the theory, extending the class of flows for which the directed percolation scenario holds and removing any remaining doubts that non-equilibrium statistical mechanical critical phenomena can be exhibited by the Navier-Stokes equations.

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“…It should be promising to follow them through their bifurcations to also reach upper branch states around which longer-lived turbulent dynamics can be observed. It should then be interesting and rewarding to relate the properties of these localized states to the patterns seen by Barkley & Tuckerman (2005) and the correlation properties of the spatiotemporal patterns described in Duguet et al (2010).…”

Section: Futurementioning

confidence: 99%

Doubly localized states in plane Couette flow

Eckhardt

2014

J. Fluid Mech.

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Much of our understanding of the transition to turbulence in flows without a linear instability came with the discovery and characterization of fully three-dimensional solutions to the Navier-Stokes equation. The first examples in plane Couette flow were periodic in both spanwise and streamwise directions, and could explain the transitions in small domains only. The presence of localized turbulent spots in larger domains, the spatiotemporal decoherence on larger scales and the ability to trigger turbulence with pointwise perturbations require solutions that are localized in both directions, like the one presented by Brand & Gibson (J. Fluid Mech., vol. 750, 2014, R3). They describe a steady solution of the Navier-Stokes equations and characterize in unprecedented detail, including an analytic computation of its localization properties. The study opens up new ways to describe localized turbulent patches.

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Formation of turbulent patterns near the onset of transition in plane Couette flow

Cited by 188 publications

References 26 publications

Turbulent bands in plane-Poiseuille flow at moderate Reynolds numbers

Turbulent bands in plane-Poiseuille flow at moderate Reynolds numbers

A statistical mechanical phase transition to turbulence in a model shear flow

Doubly localized states in plane Couette flow

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