Numerical solution of the Poisson—Boltzmann equation

The automatic three-dimensional mesh generation system for molecular geometries developed in our laboratory is used to solve the Poisson᎐Boltzmann equation numerically using a finite element method. For a number of different systems, the results are found to be in good agreement with those obtained

result (2) for a charged spherical particle and Hoskin's result A method is proposed to evaluate the accuracy of numerical (5) for two identically charged spherical particles. However, solutions of the nonlinear Poisson -Boltzmann equation for one cannot ensure that the new method is also of the sam

The network approach has been applied to derive the electrostatic potential distribution for a spheroidal colloid particle immersed in electrolyte solutions. A network model for the nonlinear Poisson-Boltzmann equation in curvilinear coordinates has been proposed. With this model and an electrical c

A modified Poisson-Boltzmann equation for symmetrical electrolytes in etectroIyte solution thecry haa been solved using a quasi-linearisation technique, Oscillations are demonstrated io the mean PO\_ tentSa and in the radial distribution fuoctions.