We simulate late-stage coarsening of a 3D symmetric binary fluid using a lattice Boltzmann method. With reduced lengths and times, l and t respectively (with scales set by viscosity, density and surface tension) our data sets cover 1 < ∼ l < ∼ 10 5 , 10 < ∼ t < ∼ 10 8 . We achieve Reynolds numbers approaching 350. At Re > ∼ 100 we find clear evidence of Furukawa's inertial scaling (l ∼ t 2/3 ), although the crossover from the viscous regime (l ∼ t) is very broad. Though it cannot be ruled out, we find no indication that Re is self-limiting (l ∼ t 1/2 ) as proposed by M. Grant and K. R. Elder [ Phys. Rev. Lett. 82, 14 (1999) ].PACS numbers: 64.75+g, 07.05. Tp, 82.20.Wt When an incompressible binary fluid mixture is quenched far below its spinodal temperature, it will phase separate into domains of different composition. Here we consider only fully symmetric 50/50 mixtures in three dimensions, for which these domains will, at late times, form a bicontinuous structure, with sharp, well-developed interfaces. The late-time evolution of this structure remains incompletely understood despite theoretical [1-4], experimental [5] and simulation [6-10] work.As emphasized by Siggia [1] and Furukawa [2], the physics of spinodal decomposition involves capillary forces, viscous dissipation, and fluid inertia. Thus, assuming that no other physics enters, the control parameters are interfacial tension σ, fluid mass density ρ, and shear viscosity η. From these can be constructed only one length, L 0 = η 2 /ρσ and one time T 0 = η 3 /ρσ 2 . We define the lengthscale L(T ) of the domain structure at time T via the structure factor S(k) as L = 2π S(k)dk/ kS(k)dk. The exclusion of other physics in late stage growth then leads us to the dynamical scaling hypothesis [1,2]: l = l(t), where we use reduced time and length variables, l ≡ L/L 0 and t ≡ (T − T int )/T 0 . Since dynamical scaling should hold only after interfaces have become sharp, and transport by molecular diffusion ignorable, we have allowed for a nonuniversal offset T int ; thereafter the scaling function l(t) should approach a universal form, the same for all (fully symmetric, deepquenched, incompressible) binary fluid mixtures.It was argued further by Furukawa [2] that, for small enough t, fluid inertia is negligible compared to viscosity, whereas for large enough t the reverse is true. Dimensional analysis then requires the following asymptotes:where, if dynamical scaling holds, amplitudes b, c (and the crossover time t * ) are universal. The Reynolds number, conventionally defined as, Re = ρ/ηLdL/dT = ll, becomes indefinitely large in the inertial regime, Eq. (2).In a recent paper, Grant and Elder have argued [4] that the Reynolds number cannot, in fact, continue to grow indefinitely. If so, Eq. (2) is not truly the large t asymptote, which must instead have l ∼ t α with α ≤ 1 2 . Grant and Elder argue that at large enough Re, turbulent remixing of the interface will limit the coarsening rate [4], so that Re stays bounded. A saturating Re (which they estimate as R...
