Flow response of a segregating mixture by interacting lattice gas simulation

Pandey, Ras B.; Gettrust, Joseph F.

doi:10.1016/j.physa.2005.03.060

Cited by 3 publications

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“…Effects of hydrostatic pressure bias (H) and molecular weight (0( = MB/MA = I -10) on steady-state density profiles have been recently examined and attempts are made to quantify the dependence of their overall density on these parameters (H, x) [43]. Very recently, we studied the response of flux density to hydrostatic pressure bias [44] in a selforganizing immiscible mixture where both components (A, B) are released into the system with equal rate. We observe linear response for both constituents with rates depending on their molecular weights, especially at low bias.…”

Section: Introductionmentioning

confidence: 99%

Eruptive flow response in a multi-component driven system by an interacting lattice gas simulation

Pandey¹,

Gettrust²

2006

Physica A: Statistical Mechanics and its Applications

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Section: Introductionmentioning

confidence: 99%

Eruptive flow response in a multi-component driven system by an interacting lattice gas simulation

Pandey¹,

Gettrust²

2006

Physica A: Statistical Mechanics and its Applications

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Correlated response in a driven flow of self-organizing particles around a slit in porous media by interacting lattice gas

Pandey

Gettrust²

2009

Phys. Rev. E

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The flow of immiscible particles (A, B) through a porous medium with a vertical slit is studied by an interacting lattice-gas computer simulation on a discrete lattice. The source of the particles is connected to the bottom and particles are driven upward by concentration gradient and a pressure bias against gravity. Distribution of flowing particles around the slit is examined as a function of the slit width and bias at high and low porosity at a steady state. At the low bias, a sharp change in the densities (high in slit to low in adjacent porous media) of both constituents occurs as expected. Onset of an undershooting in the density and mobility of particle profiles appears at the interface of slit and the porous medium on increasing the bias, an unexpected correlated response. The competition between the faster flow in the slit and slower motion of the particles in the surrounding porous medium induces stronger correlations at higher bias; as a result, a well-defined density profile emerges with higher density in the porous matrix away from the slit interface. The range of correlation and therefore the response increases on increasing the bias. Lowering the porosity to near the percolation threshold leads to the onset of oscillation in the density profile and broadening of the mobility profile, a distinct difference from the response at high porosity.

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Can a difference in molecular weights cause an eruption in a driven flow of self-organizing immiscible system?

Pandey

Gettrust

2008

Eur. Phys. J. B

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Flow response of a segregating mixture by interacting lattice gas simulation

Cited by 3 publications

References 35 publications

Eruptive flow response in a multi-component driven system by an interacting lattice gas simulation

Eruptive flow response in a multi-component driven system by an interacting lattice gas simulation

Correlated response in a driven flow of self-organizing particles around a slit in porous media by interacting lattice gas

Can a difference in molecular weights cause an eruption in a driven flow of self-organizing immiscible system?

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