Bottom-up coarse-grained models with predictive accuracy and transferability for both structural and thermodynamic properties of heptane-toluene mixtures

Dunn, Nicholas J.H.; Noid, W. G.

doi:10.1063/1.4952422

Cited by 54 publications

(66 citation statements)

References 100 publications

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“…Among them, CG model based on a rigorous bottom-up scheme (i.e. CG models developed on the basis of a FG model) are be very promising for general purpose [11][12][30][31][32][33][34]. For thermophysical fluid properties predictions, CG models based on a top-down parameterization strategy (i.e.…”

Section: Introductionmentioning

confidence: 99%

Simultaneous Description of Equilibrium, Interfacial, and Transport Properties of Fluids Using a Mie Chain Coarse-Grained Force Field

Hoang

Delage-Santacreu

Galliéro

2017

Ind. Eng. Chem. Res.

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In this work, we propose an unequivocal top-down strategy to build state independent coarse grained force fields based on the homonuclear Mie chain model. Then, this approach is applied to predict thermophysical properties (equilibrium, interfacial and transport) of nonassociating fluids from molecular simulations. Following the seminal work of Mejia et al. [Ind. Eng. Chem. Res. 53, 4131, (2014)], the proposed top-down strategy is based on an extended corresponding states principle (i.e. requiring the critical temperature, one saturated liquid density and the acentric factor for each compound) enriched by the introduction of one reference viscosity in the parameterization procedure. Molecular simulations of the sodeveloped coarse grained model representing various pure fluids (Noble gas, n-alkanes, H 2 S, CO 2 …) yield excellent results on the whole vapor-liquid equilibrium curve. Critical points, saturated densities, vapor pressures and surface tensions are accurately predicted. Saturated liquid viscosities are as well correctly predicted, which is an improvement over previous similar coarse grained models. Using classical Lorentz-Berthelot combining rules, simulations results of the pressure-composition phase diagrams of Noble gases mixtures are in good

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Section: Introductionmentioning

confidence: 99%

Simultaneous Description of Equilibrium, Interfacial, and Transport Properties of Fluids Using a Mie Chain Coarse-Grained Force Field

Hoang

Delage-Santacreu

Galliéro

2017

Ind. Eng. Chem. Res.

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“…The extended ensemble approach of Mullinax and Noid, 97 in which the coarse-grained potential is parametrised for an ensemble of systems simultaneously, allows for concentration transferable models, although at the cost of some representability compared to models parametrised for a single system. This approach was extended by Dunn and Noid 98 to include volume potentials, yielding a set of related models which, together, can give both temperature and concentration transferability. The linear pressure correction which has been applied in this work is very effective at correcting the coarse-grained pressure for a given state-point, without requiring the inclusion of any other parameters in the coarse-grained force field.…”

Section: Discussionmentioning

confidence: 99%

“…63 This was later extended to a volume matching method, which can act as a pressure correction. 64,65 However, this requires including an additional terms (volume) in the pair potential. To avoid these additional terms, we applied a pressure correction to the forcematched potentials using the iterative ramp correction described in Equation 4 (noting that this does not strictly address the statepoint dependence).…”

Section: Multiscale Coarse-graining Methods (Ms-cg): Force Matching Ofmentioning

confidence: 99%

“…Within a force matching methodology, it is usually accepted that the pressure will not be predicted correctly and that these simulations should be run at constant volume, although pressure correction based on a volume-dependent term has been proposed. 63,64 However, Figure 2 shows that a simple linear pressure correction can successfully be applied to force matched potentials within the hybrid scheme employed here.…”

Section: Densities Of Single-state Modelsmentioning

confidence: 99%

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Assessing the transferability of common top-down and bottom-up coarse-grained molecular models for molecular mixtures

Potter

Tasche

Wilson

2019

Phys. Chem. Chem. Phys.

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“…39 These issues can be sensitively dependent on chosen cut-off distances and enforced thermodynamic constraints, 39 and may be exacerbated as the complexity of the model increases due to increasing the number of distinct interactions or as the complexity of the optimization landscape increases through (i) enforcement of model restrictions (e.g., fixing a subset of parameters based on a given reference model) or (ii) incorporation of reference data from multiple state points. Moreover, structure-based potentials can be employed as a starting point for constructing CG models that also accurately represent thermodynamic [40][41][42] and dynamic [43][44][45] properties of the underlying reference model through a pressure-matching variational principle and the Mori-Zwanzig formalism, respectively. This motivates the development of direct optimization methods that can be efficiently combined with these methodologies into a unified optimization procedure.…”

Section: Introductionmentioning

confidence: 99%

Direct route to reproducing pair distribution functions with coarse-grained models via transformed atomistic cross correlations

Wörner

Bereau

Kremer

et al. 2019

The Journal of Chemical Physics

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Coarse-grained (CG) models are often parametrized to reproduce one-dimensional structural correlation functions of an atomically-detailed model along the degrees of freedom governing each interaction potential. While cross correlations between these degrees of freedom inform the optimal set of interaction parameters, the correlations generated from the higher-resolution simulations are often too complex to act as an accurate proxy for the CG correlations. Instead, the most popular methods determine the interaction parameters iteratively, while assuming that individual interactions are uncorrelated. While these iterative methods have been validated for a wide range of systems, they also have disadvantages when parametrizing models for multicomponent systems or when refining previously established models to better reproduce particular structural features. In this work, we propose two distinct approaches for the direct (i.e., non-iterative) parametrization of a CG model by adjusting the high-resolution cross correlations of an atomistic model in order to more accurately reflect correlations that will be generated by the resulting CG model. The derived models more accurately describe the low-order structural features of the underlying AA model, while necessarily generating inherently distinct cross correlations compared with the atomically-detailed reference model. We demonstrate the proposed methods for a one-site-per-molecule representation of liquid water, where pairwise interactions are incapable of reproducing the true tetrahedral solvation structure. We then investigate the precise role that distinct cross-correlation features play in determining the correct pair correlation functions, evaluating the importance of the placement of correlation features as well as the balance between features appearing in different solvation shells. arXiv:1910.04018v2 [cond-mat.soft]

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Bottom-up coarse-grained models with predictive accuracy and transferability for both structural and thermodynamic properties of heptane-toluene mixtures

Cited by 54 publications

References 100 publications

Simultaneous Description of Equilibrium, Interfacial, and Transport Properties of Fluids Using a Mie Chain Coarse-Grained Force Field

Simultaneous Description of Equilibrium, Interfacial, and Transport Properties of Fluids Using a Mie Chain Coarse-Grained Force Field

Assessing the transferability of common top-down and bottom-up coarse-grained molecular models for molecular mixtures

Direct route to reproducing pair distribution functions with coarse-grained models via transformed atomistic cross correlations

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