@article {2748,
title = {DIELECTRIC-RELAXATION OF DIPOLAR LIQUIDS},
journal = {Journal of Chemical Physics},
volume = {99},
number = {3},
year = {1993},
note = {ISI Document Delivery No.: LN782Times Cited: 19Cited Reference Count: 33},
month = {Aug},
pages = {2068-2073},
type = {Article},
abstract = {An approximate expression is derived for the dielectric function epsilon(k, omega). The theory includes inertial and non-Markovian effects and is free of adjustable parameters. For the k = 0 case, detailed comparisons are made with computer simulation results for dipolar soft-sphere and Stockmayer fluids, and the theory is shown to be qualitatively sound at both low and high frequencies. The present approximation should be very useful in developing a theory of solvation dynamics which properly includes important inertial effects.},
keywords = {COMPUTER-SIMULATION, electrostatic, equation, INVARIANT EXPANSION, ION SOLVATION, LIQUIDS, MEAN SPHERICAL MODEL, MOLECULAR LIQUIDS, ORNSTEIN-ZERNIKE, PERIODIC BOUNDARY-CONDITIONS, POLAR, SOLVATION DYNAMICS, SYSTEMS},
isbn = {0021-9606},
url = {://A1993LN78200067},
author = {Chandra, A. and Wei, D. Q. and Patey, G. N.}
}
@article {2930,
title = {ORIENTATIONAL ORDER IN SIMPLE DIPOLAR FLUIDS - DENSITY-FUNCTIONAL THEORY AND ABSOLUTE-STABILITY CONDITIONS},
journal = {Physical Review E},
volume = {47},
number = {1},
year = {1993},
note = {ISI Document Delivery No.: KY134Times Cited: 59Cited Reference Count: 29},
month = {Jan},
pages = {506-512},
type = {Article},
abstract = {The formation of ferroelectric liquid crystals by simple dipolar models is investigated using density-functional theory and absolute-stability analysis. It is emphasized that for such systems well defined results can only be found by specifying exactly how the long-range dipolar interactions are treated. Explicit formal expressions are derived for mean-reaction-field boundary conditions and these are combined with integral-equation approximations in order to obtain numerical results for fluids of dipolar hard and soft spheres. The calculations predict isotropic-to-ferroelectric-nematic transitions in qualitative agreement with computer simulations. The quantitative agreement, however, is rather poor.},
keywords = {COMPUTER-SIMULATION, ELECTROSTATIC SYSTEMS, equation, HARD-SPHERES, INVARIANT EXPANSION, MEAN SPHERICAL MODEL, ORNSTEIN-ZERNIKE, PERIODIC BOUNDARY-CONDITIONS, POLAR SYSTEMS, TRANSITION},
isbn = {1063-651X},
url = {://A1993KY13400062},
author = {Wei, D. Q. and Patey, G. N. and Perera, A.}
}