Widely applicable, modified Green-Kubo expressions for the local diffusion coefficient ($D_l$) are obtained using linear response theory. In contrast to past definitions in use, these expressions are statistical mechanical results. Molecular simulations of systems with anisotropic diffusion and an inhomogeneous density profile confirm the validity of the results. Diffusion coefficients determined from different expressions in terms of currents and velocity correlations agree in the limit of large systems. Furthermore, they apply to arbitrarily small local regions, making them readily applicable to nanoscale and inhomogeneous systems where knowledge of $D_l$ is important
Molecular transport in confined spaces is of central importance to many traditional and emerging app...
We performed a molecular dynamics simulation to calculate the self-diffusion coefficients of 1-Butyl...
Partial funding for Open Access provided by the UMD Libraries' Open Access Publishing Fund.Ab initio...
Hypothesis: Diffusion in confinement is an important fundamental problem with significant implicatio...
Translational diffusion coefficients are routinely estimated from molecular dynamics simulations. Li...
A procedure to correlate self-diffusion coefficients in dense fluids by using the perturbation theor...
The present models and simulation algorithms of intracellular kinetics are usually based on the prem...
A self-diffusionequation for a freely evolving gas of inelastic hard disks or spheres is derived sta...
SummaryReaction-diffusion systems are mathematical models that describe how the concentrations of su...
We present a detailed overview of classical molecular simulation studies examining the self-diffusio...
We consider two ways to calculate the self-diffusion coefficient of interacting Brownian particles. ...
We propose a general methodology for calculating the self-diffusion tensor from molecular dynamics (...
The coefficient of self-diffusion in three-dimensional classical liquid is computed approximately fr...
The diffusive behavior of macromolecules in solution is a key factor in the kinetics of macromolecul...
An understanding of the distance dependence of the lateral diffusion coefficient is useful in compar...
Molecular transport in confined spaces is of central importance to many traditional and emerging app...
We performed a molecular dynamics simulation to calculate the self-diffusion coefficients of 1-Butyl...
Partial funding for Open Access provided by the UMD Libraries' Open Access Publishing Fund.Ab initio...
Hypothesis: Diffusion in confinement is an important fundamental problem with significant implicatio...
Translational diffusion coefficients are routinely estimated from molecular dynamics simulations. Li...
A procedure to correlate self-diffusion coefficients in dense fluids by using the perturbation theor...
The present models and simulation algorithms of intracellular kinetics are usually based on the prem...
A self-diffusionequation for a freely evolving gas of inelastic hard disks or spheres is derived sta...
SummaryReaction-diffusion systems are mathematical models that describe how the concentrations of su...
We present a detailed overview of classical molecular simulation studies examining the self-diffusio...
We consider two ways to calculate the self-diffusion coefficient of interacting Brownian particles. ...
We propose a general methodology for calculating the self-diffusion tensor from molecular dynamics (...
The coefficient of self-diffusion in three-dimensional classical liquid is computed approximately fr...
The diffusive behavior of macromolecules in solution is a key factor in the kinetics of macromolecul...
An understanding of the distance dependence of the lateral diffusion coefficient is useful in compar...
Molecular transport in confined spaces is of central importance to many traditional and emerging app...
We performed a molecular dynamics simulation to calculate the self-diffusion coefficients of 1-Butyl...
Partial funding for Open Access provided by the UMD Libraries' Open Access Publishing Fund.Ab initio...