A Hamiltonian electrostatic coupling scheme for hybrid Car–Parrinello molecular dynamics simulations

Laio, Alessandro; VandeVondele, Joost; Röthlisberger, Ursula

doi:10.1063/1.1462041

Cited by 600 publications

(841 citation statements)

References 38 publications

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“…For this review, however, we will limit the discussion to the potential energy of interaction. Future work will deal with the inclusion of thermal and solvent effects for instance using ab initio molecular dynamics techniques [82] in conjunction with QM/MM [83] calculations. Moreover, even at the mere potential energy electronic structure level of theory, the accurate quantification and control of intercalated ellipticine derivatives is challenging: vdW forces dominate the binding.…”

Section: Control Of Ligand Bindingmentioning

confidence: 99%

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First principles view on chemical compound space: Gaining rigorous atomistic control of molecular properties

Lilienfeld

2013

Int J of Quantum Chemistry

131

158

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A well‐defined notion of chemical compound space (CCS) is essential for gaining rigorous control of properties through variation of elemental composition and atomic configurations. Here, we give an introduction to an atomistic first principles perspective on CCS. First, CCS is discussed in terms of variational nuclear charges in the context of conceptual density functional and molecular grand‐canonical ensemble theory. Thereafter, we revisit the notion of compound pairs, related to each other via “alchemical” interpolations involving fractional nuclear charges in the electronic Hamiltonian. We address Taylor expansions in CCS, property nonlinearity, improved predictions using reference compound pairs, and the ounce‐of‐gold prize challenge to linearize CCS. Finally, we turn to machine learning of analytical structure property relationships in CCS. These relationships correspond to inferred, rather than derived through variational principle, solutions of the electronic Schrödinger equation. © 2013 Wiley Periodicals, Inc.

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Section: Control Of Ligand Bindingmentioning

confidence: 99%

“…Let us exemplify a DFTþvdW-based prediction of the binding energy of another mutant: ð21121Þ is predicted to bind to the DNA cluster in Figure 4 with E 21121 ¼ À38:5 kcal/mol. [83] For predicting the single point mutation (21121) …”

Section: Tutorial Review Wwwq-chemorgmentioning

confidence: 99%

First principles view on chemical compound space: Gaining rigorous atomistic control of molecular properties

Lilienfeld

2013

Int J of Quantum Chemistry

131

158

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“…24,25 Indeed, at short distance, the validity of a point charge representation is questionable. In the context of this paper, as well as in a plane wave approach, 26 such a smearing is a convenient way of generating a charge density and a resulting Coulomb potential representable on a uniform mesh.…”

Section: Methodsmentioning

confidence: 99%

“…To address this problem in a molecular dynamics or geometry optimization context, the coordinates of some atoms at the QM frontier should be frozen so that these erroneous forces would not be active. 26 carrying out such a computation in an external Coulomb potential due to MM charges can potentially lead to the so-called electron spill-out effect. While one must be aware of this issue, the calculations reported in this paper using the parameters tabulated in Table 1 showed no measurable evidence of this phenomena.…”

Section: Methodsmentioning

confidence: 99%

Quantitative Assessment of Electrostatic Embedding in Density Functional Theory Calculations of Biomolecular Systems

Fattebert

Law

Bennion

et al. 2009

J. Chem. Theory Comput.

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We evaluate the accuracy of density functional theory quantum calculations of biomolecular subsystems using a simple electrostatic embedding scheme. Our scheme is based on dividing the system of interest into a primary and secondary subsystem. A finite difference discretization of the Kohn-Sham equations is used for the primary subsystem, while its electrostatic environment is modeled with a simple one-electron potential. Force-field atomic partial charges are used to generate smeared Gaussian charge densities and to model the secondary subsystem. We illustrate the utility of this approach with calculations of truncated dipeptide chains. We analyze quantitatively the accuracy of this approach by calculating atomic forces and comparing results with full QM calculations. The impact of the choice made in terminating dangling bonds at the frontier of the QM region is also investigated.

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“…In the context of molecular simulations, hybrid Quantum Mechanics-Molecular Mechanics (QM-MM) schemes consider the system as a sum of two parts: solute (QM fragment) and solvent (MM fragment) [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20]. The particles are assigned to one of these two groups according to their role: atoms directly involved in bonds breaking or forming, or in polarization or charge transfer effects, must be considered in the QM region, whereas those atoms not participating in these processes are included within the MM subsystem.…”

Section: Introductionmentioning

confidence: 99%

A quantum-mechanics molecular-mechanics scheme for extended systems

Hunt¹,

Sánchez²,

Scherlis³

2016

J. Phys.: Condens. Matter

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We introduce and discuss a hybrid quantum-mechanics molecular-mechanics (QM-MM) approach for Car-Parrinello DFT simulations with pseudopotentials and planewaves basis, designed for the treatment of periodic systems. In this implementation the MM atoms are considered as additional QM ions having fractional charges of either sign, which provides conceptual and computational simplicity by exploiting the machinery already existing in planewave codes to deal with electrostatics in periodic boundary conditions.With this strategy, both the QM and MM regions are contained in the same supercell, which determines the periodicity for the whole system. Thus, while this method is not meant to compete with non-periodic QM-MM schemes able to handle extremely large but finite MM regions, it is shown that for periodic systems of a few hundred atoms, our approach provides substantial savings in computational times by treating classically a fraction of the particles. The performance and accuracy of the method is assessed through the study of energetic, structural, and dynamical aspects of the water dimer and of the aqueous bulk phase. Finally, the QM-MM scheme is applied to the computation of the vibrational spectra of water layers adsorbed at the TiO 2 anatase (101) solid-liquid interface. This investigation suggests that the inclusion of a second monolayer of H 2 O molecules is sufficient to induce on the first adsorbed layer, a vibrational dynamics similar to that taking place in the presence of an aqueous environment. The present QM-MM scheme appears as a very interesting tool to efficiently perform molecular dynamics simulations of complex condensed matter systems, from solutions to nanoconfined fluids to different kind of interfaces.

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A Hamiltonian electrostatic coupling scheme for hybrid Car–Parrinello molecular dynamics simulations

Cited by 600 publications

References 38 publications

First principles view on chemical compound space: Gaining rigorous atomistic control of molecular properties

First principles view on chemical compound space: Gaining rigorous atomistic control of molecular properties

Quantitative Assessment of Electrostatic Embedding in Density Functional Theory Calculations of Biomolecular Systems

A quantum-mechanics molecular-mechanics scheme for extended systems

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