Reverse Monte Carlo simulation of liquid water

Xlonte Carlo simulations in the MJ7T-ensemble have been performed on liquid mater between two rigrd walk. Variations m denstty and in ortentation of water molecules have been calculated as a function of distance from the walls. OscilJations in .I number of properties have been found and extend sever

for water molecules is derived. The new terms are combined with previously dcvclopcd two-and three-body POtCntht tcrrnsond upplied in n hlctropolis-Monte Carlo simulation at 298 K for nn (N, I',?") ensemble with 513 water molecules. Improvements, relative to the results using only two-body, or two-a

Long Monte cylo ~tirr~ils of liqud w;~tcr at ZYC ;Lnd 1 arm hnrc brcn cxrlcd out IO study the conrergcnce chsracteristics of tic calcuhlrons. The rccenrly reported TIPS2 potenti was cmploycd ~7th system WCS oi I25 md 2 16 monomers. The cnthalpy, volume and radnl dlsmbunon fuunchons converge npldly a

A reverse Monte Carlo simulation of liquid water at room temperature is made by fitting the partial pair correlation functions of our model system to those obtained from neutron scattering experiments. The atoms in a molecule are held together by non-rigid bonds under geometric constraints. In order

Rcccived 20 February 19B5 TWO interactrng Equrd/vapor interfauzs are modelled via a grand canonical Monle Cal;0 simularion of a Lennard-Jon= 12-6 fluid. The resulmg dcnsiry profiles and interracial free energies suggest tlla~ at a cnrical separation equal IO or greater than four atomic diameters. an