Nonequilibrium steady states in fluids of platelike colloidal particles

Publication date

2008

Authors

Bier, Markus
Roij, René vanISNI 0000000392993654

Editors

Advisors

Supervisors

DOI

Document Type

Article
Open Access logo

License

Abstract

Nonequilibrium steady states in an open system connecting two reservoirs of platelike colloidal particles are investigated by means of a recently proposed phenomenological dynamic density functional theory [M. Bier and R. van Roij, Phys. Rev. E 76, 021405 (2007)]. The platelike colloidal particles are approximated within the Zwanzig model of restricted orientations, which exhibits an isotropic-nematic bulk phase transition. Inhomogeneities of the local chemical potential generate a diffusion current which relaxes to a nonvanishing value if the two reservoirs coupled to the system sustain different chemical potentials. The relaxation process of initial states towards the steady state turns out to comprise two regimes: a smoothening of initial steplike structures followed by an ultimate relaxation of the slowest diffusive mode. The position of a nonequilibrium interface and the particle current of steady states depend nontrivially on the structure of the reservoirs due to the coupling between translational and orientational degrees of freedom of the fluid.

Keywords

Citation

Bier, M & van Roij, R H H G 2008, 'Nonequilibrium steady states in fluids of platelike colloidal particles', Physical Review E - Statistical, Nonlinear, and Soft Matter Physics, vol. 77, no. 021401, pp. 1-7.