4.7 Article

Linear instability of viscoelastic pipe flow

期刊

JOURNAL OF FLUID MECHANICS
卷 908, 期 -, 页码 -

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CAMBRIDGE UNIV PRESS
DOI: 10.1017/jfm.2020.822

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transition to turbulence

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A modal stability analysis reveals that pressure-driven pipe flow of an Oldroyd-B fluid is linearly unstable to axisymmetric perturbations, in contrast to Newtonian fluids. The critical Reynolds number for instability diverges in certain asymptotic limits, with the unstable mode localized near the centerline. The study suggests that this linear instability may play a significant role in the onset of turbulence in viscoelastic pipe flows, challenging the prevailing notion of linear stability in such flow conditions.
A modal stability analysis shows that pressure-driven pipe flow of an Oldroyd-B fluid is linearly unstable to axisymmetric perturbations, in stark contrast to its Newtonian counterpart which is linearly stable at all Reynolds numbers. The dimensionless groups that govern stability are the Reynolds number Re = rho UmaxR/eta, the elasticity number E = lambda eta/(R-2 rho) and the ratio of solvent to solution viscosity beta = eta(s)/eta; here, R is the pipe radius, U-max is the maximum velocity of the base flow, rho is the fluid density and lambda is the microstructural relaxation time. The unstable mode has a phase speed close to U-max over the entire unstable region in (Re, E, beta) space. In the asymptotic limit E(1 - beta) << 1, the critical Reynolds number for instability diverges as Re-c similar to (E(1 - beta))(-3/2), the critical wavenumber increases as k(c) similar to (E(1 - beta))(-1/2), and the unstable eigenfunction is localized near the centreline, implying that the unstable mode belongs to a class of viscoelastic centre modes. In contrast, for beta -> 1 and E similar to 0.1, Re-c can be as low as O(100), with the unstable eigenfunction no longer being localized near the centreline. Unlike the Newtonian transition which is dominated by nonlinear processes, the linear instability discussed in this study could be very relevant to the onset of turbulence in viscoelastic pipe flows. The prediction of a linear instability is, in fact, consistent with several experimental studies on pipe flow of polymer solutions, ranging from reports of 'early turbulence' in the 1970s to the more recent discovery of 'elasto-inertial turbulence' (Samanta et al., Proc. Natl Acad. Sci. USA, vol. 110, 2013, pp. 10557-10562). The instability identified in this study comprehensively dispels the prevailing notion of pipe flow of viscoelastic fluids being linearly stable in the Re-W plane (W = Re E being the Weissenberg number), marking a possible paradigm shift in our understanding of transition in rectilinear viscoelastic shearing flows. The predicted unstable eigenfunction should form a template in the search for novel nonlinear elasto-inertial states, and could provide an alternate route to the maximal drag-reduced state in polymer solutions. The latter has thus far been explained in terms of a viscoelastic modification of the nonlinear Newtonian coherent structures.

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