Abstract When decaying to laminar flow from uniform turbulence at decreasing Reynolds number R, wall-bounded flows often display a complex regime made of coexisting laminar and turbulent domains in a range Rg,. The ultimate decay at Rg is well understood as a directed percolation (DP) process representative of a non-equilibrium universality class. The status of the pattern's emergence at Rt is much less clear-cut. Here, we study this problem in the emblematic case of flow between counter-translating parallel plates, plane Couette flow. Through numerical simulations in an extended domain, we demonstrate that this phenomenon exhibits characteristics consistent with a second-order phase transition. Ginzburg-Landau-like envelopes derived from turbulence modulations serve to define order parameters. The variance of their temporal fluctuations (conjugate susceptibilities in the phase transition context) and the coherence lengths extracted from their spatial autocorrelations show diverging trends as the threshold Rt=408. 4±0. 2 is approached. The exponents corresponding to these divergences, =0. 53±0. 03 and =0. 074±0. 004, appear significantly different from the classical values cl. =1 and cl=1/2, signalling unconventional critical properties. We discuss the possibility that these findings could be archetypal of an original out-of-equilibrium universality class at Rt, like the DP universality class observed at Rg.
Manneville et al. (Wed,) studied this question.
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