Adaptive resolution molecular dynamics simulation through coupling to an internal particle reservoir

Fritsch, Sebastian; Poblete, Simón; Junghans, Christoph; Ciccotti, Giovanni; Site, Luigi Delle; Kremer, Kurt

doi:10.1103/physrevlett.108.170602

Cited by 140 publications

(235 citation statements)

References 37 publications

(36 reference statements)

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“…(47) is valid for any Hamiltonian system: notably, this intimate relation between the force density field and the density gradients is independent on the fluid compressibility. It explains the essence of many algorithms [15][16][17] designed to impose a flat density profile by adding an external force "correction" to the system (which, according to Eq. (47) has to ensure vanishing total force density field f r = 0).…”

Section: B the Stress And The Pressurementioning

confidence: 99%

“…This relation explains the basis of the "correction force field" used to control the density profile, not only in Ref. 15 but also in many other algorithms using domain decomposition (see, e.g., Refs. 16 and 17).…”

Section: Introductionmentioning

confidence: 99%

“…5 Density fluctuations are determined by the fluid compressibility, specified by the integral of the radial distribution function, and by finely tuning the CG potential one can match the compressilibities of the CG and AA domains. Having the same compressibility does not however ensure the same pressure equation of state and to ensure a constant density profile over the CG and AA domains, a recent work 15 proposes the imposition of a "correction force field," which is iteratively evaluated according to the idea of imposing pressure balance (and thus involving compressibilities). The existence of a Hamiltonian permits us to derive a fundamental relation between the force density and the density gradient, which turns out to be independent on the compressibility.…”

Section: Introductionmentioning

confidence: 99%

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Statistical mechanics of Hamiltonian adaptive resolution simulations

Español

Delgado‐Buscalioni

Everaers

et al. 2015

The Journal of Chemical Physics

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The Adaptive Resolution Scheme (AdResS) is a hybrid scheme that allows to treat a molecular system with different levels of resolution depending on the location of the molecules. The construction of a Hamiltonian based on the this idea (H-AdResS) allows one to formulate the usual tools of ensembles and statistical mechanics. We present a number of exact and approximate results that provide a statistical mechanics foundation for this simulation method. We also present simulation results that illustrate the theory. C 2015 AIP Publishing LLC. [http://dx

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Section: B the Stress And The Pressurementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Statistical mechanics of Hamiltonian adaptive resolution simulations

Español

Delgado‐Buscalioni

Everaers

et al. 2015

The Journal of Chemical Physics

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“…In particular, the chemical potential gradient, which is generally established across the transition region, would have to be counterbalanced [29]. This idea leads to the following form of the compensation term in Eq.…”

Section: Introduces In the Hybrid Region A Drift Force Which Violatesmentioning

confidence: 99%

“…The method is nonetheless robust, since it allows us to define temperature, pressure and density everywhere, and the introduction of a thermodynamic force [28] in the transition zone paved the way to open system MD simulations [20,29]. Despite the success of the force-interpolation based AdResS method, though, the lack of a Hamiltonian description in the transition region is a drawback: it hampers a general statistical theory for the whole setup, limits the choice of the simulation ensemble and prevents Monte Carlo simulations.…”

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confidence: 99%

Hamiltonian Adaptive Resolution Simulation for Molecular Liquids

et al. 2013

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Adaptive resolution schemes allow the simulation of a molecular fluid treating simultaneously different subregions of the system at different levels of resolution. In this work we present a new scheme formulated in terms of a global Hamiltonian. Within this approach equilibrium states corresponding to well defined statistical ensembles can be generated making use of all standard Molecular Dynamics or Monte Carlo methods. Models at different resolutions can thus be coupled, and thermodynamic equilibrium can be modulated keeping each region at desired pressure or density without disrupting the Hamiltonian framework.

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Structural Locality and Early Stage of Aggregation of Micelles in Water: An Adaptive Resolution Molecular Dynamics Study

Jabes

Klein

Site

2018

Advcd Theory and Sims

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The adaptive resolution simulation technique is employed to perform molecular dynamics simulations of a single micelle and two micelles in water. It is shown how, by identifying the essential atomistic degrees of freedom in the solvation process, the adaptive technique can be used to devise an optimal strategy for studying the aggregation of two micelles with atomistic accuracy and at a reduced computational cost. Atomistic accuracy is highly desired in such studies; in fact, if any water-mediated effect that requires the explicit hydrogen bond network is present, then the adaptive resolution will be able to describe it. Instead, this is not possible if a generic coarse-grained model, for example, spherical molecules without orientational bonds, is employed. In particular, the potential of mean force for the aggregation of two micelles is calculated and it is shown that the results obtained agree in a satisfactory way with the full atomistic simulation of reference. In perspective, this paper offers an example of how similar systems/problems can be efficiently treated with the adaptive resolution technique.

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Adaptive resolution molecular dynamics simulation through coupling to an internal particle reservoir

Cited by 140 publications

References 37 publications

Statistical mechanics of Hamiltonian adaptive resolution simulations

Statistical mechanics of Hamiltonian adaptive resolution simulations

Hamiltonian Adaptive Resolution Simulation for Molecular Liquids

Structural Locality and Early Stage of Aggregation of Micelles in Water: An Adaptive Resolution Molecular Dynamics Study

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