Relative resolution: A hybrid formalism for fluid mixtures

Abstract: We show here that molecular resolution is inherently hybrid in terms of relative separation. While nearest neighbors are characterized by a fine-grained (geometrically detailed) model, other neighbors are characterized by a coarse-grained (isotropically simplified) model. We notably present an analytical expression for relating the two models via energy conservation. This hybrid framework is correspondingly capable of retrieving the structural and thermal behavior of various multi-component and multi-phase flu… Show more

“…Conversely, we developed an analytical parameterization between the FG and CG models, which is just based on energy conservation [1]. Unlike those other strategies [38,39], we were consequently able of correctly retrieving across state space, the structural and thermal behavior of several nonpolar mixtures [1]. Besides, we showed that our hybrid approach can be considered as a generalized extension of established theories for uniform liquids, which assume a mean field for interactions beyond a certain distance [40,41,42,43].…”

“…Once the two models are analytically connected with each other via energy conservation, Relative Resolution can capture the structural and thermal behavior of (nonpolar) multi-component and multi-phase systems across state space. The current work is a natural continuation of our original communication [1]. Most importantly, we present the comprehensive mathematics of Relative Resolution, basically casting it as a multipole approximation at appropriate distances; the current set of equations importantly applies for all systems (e.g, polar molecules).…”

“…Very recently, we developed another type of multiscale methods, termed Relative Resolution (RelRes) [1]. Inspired by Adaptive Resolution, this approach is a "two-body distance-based" multiscale method: In a single molecular simulation, hybrid molecules switch their resolution in terms of relative separation; in particular, molecules that are near neighbors (i.e., their pairwise distance is small) interact via their FG models, and molecules that are far neighbors (i.e., their pairwise distance is large) interact via their CG models [1]. Importantly, RelRes is the sole class of multiscale simulations which describes all molecules, for all times, with both FG and CG models; the resolution of a given molecule is always relative of its observer.…”

“…[39] does not make a clear connection between the two models. Conversely, we developed an analytical parameterization between the FG and CG models, which is just based on energy conservation [1]. Unlike those other strategies [38,39], we were consequently able of correctly retrieving across state space, the structural and thermal behavior of several nonpolar mixtures [1].…”

“…In this current work, we build on our original communication of RelRes [1]. Foremost, we mathematically present the comprehensive framework for RelRes.…”

Relative resolution: Multipole approximation at appropriate distances

“…Conversely, we developed an analytical parameterization between the FG and CG models, which is just based on energy conservation [1]. Unlike those other strategies [38,39], we were consequently able of correctly retrieving across state space, the structural and thermal behavior of several nonpolar mixtures [1]. Besides, we showed that our hybrid approach can be considered as a generalized extension of established theories for uniform liquids, which assume a mean field for interactions beyond a certain distance [40,41,42,43].…”

“…Once the two models are analytically connected with each other via energy conservation, Relative Resolution can capture the structural and thermal behavior of (nonpolar) multi-component and multi-phase systems across state space. The current work is a natural continuation of our original communication [1]. Most importantly, we present the comprehensive mathematics of Relative Resolution, basically casting it as a multipole approximation at appropriate distances; the current set of equations importantly applies for all systems (e.g, polar molecules).…”

“…Very recently, we developed another type of multiscale methods, termed Relative Resolution (RelRes) [1]. Inspired by Adaptive Resolution, this approach is a "two-body distance-based" multiscale method: In a single molecular simulation, hybrid molecules switch their resolution in terms of relative separation; in particular, molecules that are near neighbors (i.e., their pairwise distance is small) interact via their FG models, and molecules that are far neighbors (i.e., their pairwise distance is large) interact via their CG models [1]. Importantly, RelRes is the sole class of multiscale simulations which describes all molecules, for all times, with both FG and CG models; the resolution of a given molecule is always relative of its observer.…”

“…[39] does not make a clear connection between the two models. Conversely, we developed an analytical parameterization between the FG and CG models, which is just based on energy conservation [1]. Unlike those other strategies [38,39], we were consequently able of correctly retrieving across state space, the structural and thermal behavior of several nonpolar mixtures [1].…”

“…In this current work, we build on our original communication of RelRes [1]. Foremost, we mathematically present the comprehensive framework for RelRes.…”

Relative resolution: Multipole approximation at appropriate distances

A different approach to dual-scale models

Molecular systems with open boundaries: Theory and simulation