Showing total 2 results

1. Electrofreezing of confined water

Author

Alan E. Mark, Ronen Zangi, Groningen Biomolecular Sciences and Biotechnology, and Molecular Dynamics

Subjects

Phase transition, LIQUID WATER, DIELECTRIC SATURATION, MOLECULAR-DYNAMICS SIMULATIONS, Ice crystals, Condensed matter physics, Hydrogen bond, Chemistry, Shell (structure), General Physics and Astronomy, VYCOR GLASS, ELECTRIC-FIELD, Molecular dynamics, Crystallography, Molecular geometry, MONTE-CARLO, NEUTRON-SCATTERING, Phase (matter), Electric field, X-RAY, PHASE-TRANSITIONS, Physical and Theoretical Chemistry, BILAYER ICE

Abstract

We report results from molecular dynamics simulations of the freezing transition of TIP5P water molecules confined between two parallel plates under the influence of a homogeneous external electric field, with magnitude of 5 V/nm, along the lateral direction. For water confined to a thickness of a trilayer we find two different phases of ice at a temperature of T=280 K. The transformation between the two, proton-ordered, ice phases is found to be a strong first-order transition. The low-density ice phase is built from hexagonal rings parallel to the confining walls and corresponds to the structure of cubic ice. The high-density ice phase has an in-plane rhombic symmetry of the oxygen atoms and larger distortion of hydrogen bond angles. The short-range order of the two ice phases is the same as the local structure of the two bilayer phases of liquid water found recently in the absence of an electric field [J. Chem. Phys. 119, 1694 (2003)]. These high- and low-density phases of water differ in local ordering at the level of the second shell of nearest neighbors. The results reported in this paper, show a close similarity between the local structure of the liquid phase and the short-range order of the corresponding solid phase. This similarity might be enhanced in water due to the deep attractive well characterizing hydrogen bond interactions. We also investigate the low-density ice phase confined to a thickness of 4, 5, and 8 molecular layers under the influence of an electric field at T=300 K. In general, we find that the degree of ordering decreases as the distance between the two confining walls increases. (C) 2004 American Institute of Physics.

Published

2004

2. Calculating fifth-order Raman signals for various molecular liquids by equilibrium and nonequilibrium hybrid molecular dynamics simulation algorithms

Author

Yoshitaka Tanimura and Taisuke Hasegawa

Subjects

Formamide, Analytical chemistry, General Physics and Astronomy, chemistry.chemical_element, Non-equilibrium thermodynamics, Molecular physics, symbols.namesake, chemistry.chemical_compound, Molecular dynamics, Xenon, chemistry, Polarizability, Molecular vibration, symbols, Physical and Theoretical Chemistry, Raman spectroscopy, Excitation

Abstract

The fifth-order two-dimensional (2D) Raman signals have been calculated from the equilibrium and nonequilibrium (finite field) molecular dynamics simulations. The equilibrium method evaluates response functions with equilibrium trajectories, while the nonequilibrium method calculates a molecular polarizability from nonequilibrium trajectories for different pulse configurations and sequences. In this paper, we introduce an efficient algorithm which hybridizes the existing two methods to avoid the time-consuming calculations of the stability matrices which are inherent in the equilibrium method. Using nonequilibrium trajectories for a single laser excitation, we are able to dramatically simplify the sampling process. With this approach, the 2D Raman signals for liquid xenon, carbon disulfide, water, acetonitrile, and formamide are calculated and discussed. Intensities of 2D Raman signals are also estimated and the peak strength of formamide is found to be only five times smaller than that of carbon disulfide.

Published

2006