The dielectric constant of a polar liquid by the simulation of microscopic drops

A Monk Carlo swdy of [he slalic dielctxic consLant of a fluid of polar hard spheres is presented. For fined values of lhe dipole moment. it is found that Ihe dielectric constant is essentially independent of Ihc charge scparatinn. This esIablishes that lhe decrease in dielceuic constam for polar har

We present a successful calculation of the static dielectric constant of water based on simulations of microscopic droplets in vacuum. A 1.5 ns simulation of a 24 ~ radius sphere of TIP3P water gives ~ -82 + 5 at 292 K; a 2 ns simulation of a 14 sphere gives • ffi 82 + 5 at 294 K. Inclusion of all e

The purpose of this paper is to examine a simple polar-polarizable model for liquid ammonia. Theoretical values of the mean molecular dipole moment and the static dielectric constant are reported for temperatures ranging from -70°C to 35°C. The theoretical results are obtained by solving the self-co

Recently, we have developed a new water potential (J. Phys. Chem. 100 (1996) 2723), which gives good descriptions of water and provides a 6-7 fold increase in computational speed in Monte Carlo simulations when compared to existing multi-site models. Here, the static dielectric constant of this mode