Poiseuille flow and the thermomolecular effect in a plane slit and a cylindrical capillary

A version of the discrete-ordinates method is used to solve, for the case of flow in a cylindrical tube, the classical Poiseuille and thermal-creep problems based on the Bhatnagar, Gross, and Krook model in the theory of rarefied-gas dynamics. In addition to the development of a discrete-ordinates s

4 difference method for treating the complete two-dimensional Navier-Stokes equations in time-dependent form is applied to the prediction of incipient turbulence. A steady laminar flow profile is disturbed and the propagation of disturbances in time and space is calculated. Changes occur in amplitud

A direct numerical scheme is developed to study the temporal ampli®cation of a 2D disturbance in plane Poiseuille ¯ow. The transient non-linear Navier±Stokes equations are applied in a region of wavelength moving with the wave propagation speed. The complex amplitude involved in the perturbation fun

Density functional theory is applied to a Lennard-Jones fluid near a single hard wall and in a slit formed by two walls. We use some simplified versions of the Weeks-Chandler-Andersen (WCA) and the Barker-Henderson (BH) theories. Only the most crude mean field version of the WCA theory, in which the