Various methods for simulating materials and minerals at an atomic level are reviewed, including lattice energy relaxation, lattice dynamics, molecular dynamics and Monte \ud Carlo methods, and including also the use of empirical interatomic potentials and ab-initio quantum mechanical methods. A small number of diverse applications are \ud described. Approaches to job and data management are also discussed
Theory and computation play an increasingly important role in the field of mineral physics by allowi...
All-atom simulations can provide molecular-level insights into the dynamics of gas-phase, condensed-...
Atomistic simulation has been employed to generate models with ever increasing structural complexity...
Various methods for simulating materials and minerals at an atomic level are reviewed, including lat...
Theory and application of atomistic computer simulations to model, understand, and predict the prope...
This chapter introduces fundamental computational approaches and ideas to energy materials. These ca...
Atomistic simulation technique such as first-principles, molecular dynamics and Monte Carlo methods ...
Atomistic simulations such as molecular dynamics and Monte Carlo are widely used for understanding t...
The interface of quantum mechanics methods with classical atomistic simulation techniques, such as m...
The following six papers were presented at a meeting, held in September 1994, which reviewed some of...
Basic concepts of computer modeling in science and engineering using discrete particle systems and c...
With developments of semi-empirical interatomic potentials for realistic materials systems, atomisti...
The present work on the molecular dynamics method covers the theoretical background of the method an...
The micro- to nano-sized nature of layered materials, particularly characteristic of naturally occur...
This article discusses computational analysis methods typically used in atomistic modeling of cryst...
Theory and computation play an increasingly important role in the field of mineral physics by allowi...
All-atom simulations can provide molecular-level insights into the dynamics of gas-phase, condensed-...
Atomistic simulation has been employed to generate models with ever increasing structural complexity...
Various methods for simulating materials and minerals at an atomic level are reviewed, including lat...
Theory and application of atomistic computer simulations to model, understand, and predict the prope...
This chapter introduces fundamental computational approaches and ideas to energy materials. These ca...
Atomistic simulation technique such as first-principles, molecular dynamics and Monte Carlo methods ...
Atomistic simulations such as molecular dynamics and Monte Carlo are widely used for understanding t...
The interface of quantum mechanics methods with classical atomistic simulation techniques, such as m...
The following six papers were presented at a meeting, held in September 1994, which reviewed some of...
Basic concepts of computer modeling in science and engineering using discrete particle systems and c...
With developments of semi-empirical interatomic potentials for realistic materials systems, atomisti...
The present work on the molecular dynamics method covers the theoretical background of the method an...
The micro- to nano-sized nature of layered materials, particularly characteristic of naturally occur...
This article discusses computational analysis methods typically used in atomistic modeling of cryst...
Theory and computation play an increasingly important role in the field of mineral physics by allowi...
All-atom simulations can provide molecular-level insights into the dynamics of gas-phase, condensed-...
Atomistic simulation has been employed to generate models with ever increasing structural complexity...