n this work, we provide a detailed theoretical analysis, supported by numerical tests, of the reliability of the adaptive resolution simulation (AdResS) technique in sampling the Grand Canonical ensemble. We demonstrate that the correct density and radial distribution functions in the hybrid region, where molecules change resolution, are two necessary conditions for considering the atomistic and coarse-grained regions in AdResS equivalent to subsystems of a full atomistic system with an accuracy up to the second order with respect to the probability distribution of the system. Moreover, we show that the work done by the thermostat and a thermodynamic force in the transition region is formally equivalent to balance the chemical potential dif...
This article deals with the molecular dynamics simulation of open systems that can exchange energy a...
Quantum effects due to the spatial delocalization of light atoms are treated in molecular simulation...
In a previous paper, a precise relation between the chemical potential of a fully atomistic simulati...
The AdResS method in molecular dynamics (MD) allows, in a grand canonical (GC) fashion, to change on...
We investigate the role of the thermodynamic (TD) force, as an essential and sufficient technical in...
The Adaptive Resolution Scheme (AdResS) is a hybrid scheme that allows to treat a molecular system w...
For simulation studies of (macro) molecular liquids it would be of significant interest to be able t...
For simulation studies of (macro) molecular liquids it would be of significant interest to be able t...
The adaptive resolution simulation (AdResS) technique couples regions with different molecular resol...
We employ the adaptive resolution approach AdResS, in its recently developed Grand Canonical-like ve...
In this paper, we investigate the equilibrium statistical properties of both the force and potential...
This thesis work is devoted to the conceptual and technical development of the Adaptive Resolution S...
Computer simulations have become a fundamental tool in molecular soft matter research. For example, ...
In adaptive resolution simulations, molecular fluids are modeled employing different levels of resol...
We have implemented the Centroid Molecular Dynamics scheme (CMD) into the Grand Canonical-like versi...
This article deals with the molecular dynamics simulation of open systems that can exchange energy a...
Quantum effects due to the spatial delocalization of light atoms are treated in molecular simulation...
In a previous paper, a precise relation between the chemical potential of a fully atomistic simulati...
The AdResS method in molecular dynamics (MD) allows, in a grand canonical (GC) fashion, to change on...
We investigate the role of the thermodynamic (TD) force, as an essential and sufficient technical in...
The Adaptive Resolution Scheme (AdResS) is a hybrid scheme that allows to treat a molecular system w...
For simulation studies of (macro) molecular liquids it would be of significant interest to be able t...
For simulation studies of (macro) molecular liquids it would be of significant interest to be able t...
The adaptive resolution simulation (AdResS) technique couples regions with different molecular resol...
We employ the adaptive resolution approach AdResS, in its recently developed Grand Canonical-like ve...
In this paper, we investigate the equilibrium statistical properties of both the force and potential...
This thesis work is devoted to the conceptual and technical development of the Adaptive Resolution S...
Computer simulations have become a fundamental tool in molecular soft matter research. For example, ...
In adaptive resolution simulations, molecular fluids are modeled employing different levels of resol...
We have implemented the Centroid Molecular Dynamics scheme (CMD) into the Grand Canonical-like versi...
This article deals with the molecular dynamics simulation of open systems that can exchange energy a...
Quantum effects due to the spatial delocalization of light atoms are treated in molecular simulation...
In a previous paper, a precise relation between the chemical potential of a fully atomistic simulati...