This book discusses the fundamentals of molecular simulation, starting with the basics of statistical mechanics and providing introductions to Monte Carlo and molecular dynamics simulation techniques. It also offers an overview of force-field models for molecular simulations and their parameterization, with a discussion of specific aspects. The book then summarizes the available know-how for analyzing molecular simulation outputs to derive information on thermophysical and structural properties. Both the force-field modeling and the analysis of simulation outputs are illustrated by various examples. Simulation studies on recently introduced HFO compounds as working fluids for different technical applications demonstrate the value of molecular simulations in providing predictions for poorly understood compounds and gaining a molecular-level understanding of their properties. This book will prove a valuable resource to researchers and students alike.

There are many tools available to measure the thermophysical properties of compounds. Experimental measurements have been evolving for many years and are very accurate at determining the properties of most compounds. However, many of the measurements are unreliable when the compound of interest is thermally unstable. Throughout the years molecular simulation techniques have been developed to understand the thermophysical properties of thermally unstable compounds. There are primarily two methods to study Vapor-Liquid Equilibrium by molecular simulation Gibbs Ensemble Monte Carlo and Molecular Dynamics. MD is a technique that allows one to simulate the vapor and the liquid in the same simulation cell. The advantage to having the vapor and liquid in the same simulation cell is that an interface forms and properties not available by GEMC can be investigated. However, the inclusion of the interface complicates the determination of the phase densities. There are two methods available in the literature to determine the phase densities from a two-phase MD simulation. The first utilizes a hyperbolic tangent function to fit the density profile across the axis normal to the interface. The second method calculates the average of a local property spatially and then determines the resulting distribution function. The distribution function is used to determine the phases from user defined phase cut-offs. These methods only work well far from the critical point and have many adjustable parameters. These adjustable parameters make it difficult to reliably obtain accurate results. This lack of reliability is one of the main driving forces behind this dissertation. In order to correct the limitations of previous methods, a new technique is presented and tested against three cases. The new technique utilizes Voronoi tessellations to calculate the volume of every molecule in the simulation cell. The molecular volumes generated can be interpreted by simple statistical parameters such as the mean and variance to determine the density on the two phase envelope. In this dissertation a new method is presented and applied to three test cases, a simple fluid, and two polyatomic cases.

This book is concerned with the prediction of thermodynamic and transport properties of gases and liquids. The prediction of such properties is essential for the solution of many problems encountered in chemical and process engineering as well as in other areas of science and technology. The book aims to present the best of those modern methods which are capable of practical application. It begins with basic scientific principles and formal results which are subsequently developed into practical methods of prediction. Numerous examples, supported by a suite of computer programmes, illustrate applications of the methods. The book is aimed primarily at the student market (for both undergraduate and taught postgraduate courses) but it will also be useful for those engaged in research and for chemical and process engineering professionals.

This book assists in the exchange of research and progress outcomes concerned with the latest issues in thermophysical properties (TPPs) of complex liquids research, development, and production. Topics cover the control of transport properties of metallic alloys, thermal analysis of complex plasmas and instabilities in plasma devices, thermophysical properties at nanolevel, theoretical background of viscosities of hydrocarbons at varying temperature and pressure ranges, molecular modeling, and experimental investigations based on nanofluids and ionic conduction in solid-state electrolytes for thermodynamic data. This book enables global researchers to tackle the challenges that continue to generate cost-effective TPPs and the latest understanding in the development of complex materials and the collaboration of modern thermophysical generating technologies. Moreover, it provides a platform for different regional authors to exchange scientific knowledge and generate enthusiasm for science and technology.

Book & CD. Computer molecular simulations of complex multi-particle systems play a fascinating role in fundamental physics, biochemical and life sciences. Having an increasingly significant impact on many applied industries, especially in modern biophysical and nanotechnological areas, molecular simulation provides a set of tools for predicting many functional properties of molecular systems. The chemical, pharmaceutical, materials and related industries -- all share the computer molecular simulation methods. The molecular simulation studies cover different fields of either biological processes -- protein folding and electron densities of DNA and proteins, or thin film formations and surface-cluster phenomena in nanoelectronics, synthetic copolymers and biopolymer design in biochemistry, so on. Practically all of the world's present supercomputers and many specially developed high performance computing clusters over the world are performing molecular simulations or are aimed on these needs. This book presents leading international research in this dynamic field.