Andrew K. Gunstensen scite author profile

We introduce a lattice Boltzmann model for simulating immiscible binary fluids in two dimensions. The model, based on the Boltzmann equation of lattice-gas hydrodynamics, incorporates features of a previously introduced discrete immiscible lattice-gas model. A theoretical value of the surface-tension coefficient is derived and found to be in excellent agreement with values obtained from simulations. The model serves as a numerical method for the simulation of immiscible twophase flow; a preliminary application illustrates a simulation of flow in a two-dimensional microscopic model of a porous medium. Extension of the model to three dimensions appears straightforward.

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Lattice‐Boltzmann studies of immiscible two‐phase flow through porous media

Gunstensen¹,

Rothman²

1993

J. Geophys. Res.

148

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Using a recently introduced numerical technique known as a lattice-Boltzmann method, we numerically investigate immiscible two-phase flow in a three-dimensional microscopic model of a porous medium and attempt to establish the form of the macroscopic flow law. We observe that the conventional linear description of the flow is applicable for high levels of forcing when the relative effects of capillary forces are small. However, at low levels of forcing capillary effects become important and the flow law becomes nonlinear. By constructing a two-dimensional phase diagram in the parameter space of nonwetting saturation and dimensionless forcing, we delineate the various regions of linearity and nonlinearity and attempt to explain the underlying physical mechanisms that create these regions. In particular, we show that the appearance of percolated, throughgoing flow paths depends not only on the relative concentrations of the two fluids but also on a dimensionless number that represents the ratio of the applied force to the force necessary for nonwetting fluid to fully penetrate through the porous medium. Finally, we fit a linear model to our simulation data in the high-forcing regions of the system and observe that an Onsager reciprocity holds for the viscous coupling of the two fluids. ß e ß e c ß ß ß ß ß ß e %, ß E ? Macmillan, New York, 1960. Wolfram, S., Cellular automaton fluids, 1, Basic theory, J. Stat. Phys., 45,471-526, 1986. Zanetti, G., The hydrodynamics of lattice gas automata, Phys. Rev A,

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Microscopic Modeling of Immiscible Fluids in Three Dimensions by a Lattice Boltzmann Method

Gunstensen

Rothman

1992

Europhys. Lett.

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A lattice-gas model for three immiscible fluids

Gunstensen

Rothman

1991

Physica D: Nonlinear Phenomena

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A Galilean-invariant immiscible lattice gas

Gunstensen

Rothman

1991

Physica D: Nonlinear Phenomena

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