<i>
                     <i>Ab initio</i>
                  </i> molecular dynamics simulation of liquid water by quantum Monte Carlo

Zen, Andrea; Luo, Ye; Mazzola, Guglielmo; Guidoni, Leonardo; Sorella, Sandro

doi:10.1063/1.4917171

Cited by 73 publications

(68 citation statements)

References 80 publications

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“…For small gas phase molecules higher-level methods, such as coupled cluster theory, can also be utilized with PIMD simulations (253). In addition recent simulations of liquid water using highly accurate quantum Monte Carlo surfaces suggest that PIMD simulations of this kind might soon become practical (254). New accurate intermolecular potential energy surfaces, such as MB-pol, also present new opportunities for identifying more accurately the role of NQEs in pure water (27,(255)(256)(257).…”

Section: Potential Energy Surfacesmentioning

confidence: 99%

Nuclear Quantum Effects in Water and Aqueous Systems: Experiment, Theory, and Current Challenges

et al. 2016

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Nuclear quantum effects influence the structure and dynamics of hydrogen bonded systems, such as water, which impacts their observed properties with widely varying magnitudes. This review highlights the recent significant developments in the experiment, theory and simulation of nuclear quantum effects in water. Novel experimental techniques, such as deep inelastic neutron scattering, now provide a detailed view of the role of nuclear quantum effects in water's 2 properties. These have been combined with theoretical developments such as the introduction of the competing quantum effects principle that allows the subtle interplay of water's quantum effects and their manifestation in experimental observables to be explained. We discuss how this principle has recently been used to explain the apparent dichotomy in water's isotope effects, which can range from very large to almost nonexistent depending on the property and conditions. We then review the latest major developments in simulation algorithms and theory that have enabled the efficient inclusion of nuclear quantum effects in molecular simulations, permitting their combination with on-the-fly evaluation of the potential energy surface using electronic structure theory. Finally, we identify current challenges and future opportunities in the area.3

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Section: Potential Energy Surfacesmentioning

confidence: 99%

Nuclear Quantum Effects in Water and Aqueous Systems: Experiment, Theory, and Current Challenges

et al. 2016

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“…[14][15][16][17]). Of the various methods available, diffusion Monte Carlo (DMC) is particularly attractive [18][19][20][21][22][23][24]. First, DMC has already been shown to offer the requisite accuracy for bulk ice phases by producing results in excellent agreement with experiment [11,12,25,26].…”

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confidence: 99%

Evidence for stable square ice from quantum Monte Carlo

et al. 2016

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Recent experiments on ice formed by water under nanoconfinement provide evidence for a two-dimensional (2D) "square ice" phase. However, the interpretation of the experiments has been questioned and the stability of square ice has become a matter of debate. Partially this is because the simulation approaches employed so far (force fields and density functional theory) struggle to accurately describe the very small energy differences between the relevant phases. Here we report a study of 2D ice using an accurate wave-function based electronic structure approach, namely diffusion Monte Carlo (DMC). We find that at relatively high pressure, square ice is indeed the lowest enthalpy phase examined, supporting the initial experimental claim. Moreover, at lower pressures, a "pentagonal ice" phase (not yet observed experimentally) has the lowest enthalpy, and at ambient pressure, the "pentagonal ice" phase is degenerate with a "hexagonal ice" phase. Our DMC results also allow us to evaluate the accuracy of various density functional theory exchange-correlation functionals and force field models, and in doing so we extend the understanding of how such methodologies perform to challenging 2D structures presenting dangling hydrogen bonds. DOI: 10.1103/PhysRevB.94.220102 Recent transmission electron microscopy (TEM) measurements and classical molecular dynamics simulations report that a new two-dimensional (2D) square phase of ice forms [1]. This phase is not part of the bulk ice phase diagram, but it was suggested that it is stabilized under confinement because of lateral pressure, estimated to be in the gigapascal (GPa), arising from the van der Waals (vdW) attraction between the graphene sheets. However, these experiments have been questioned [2], with it even being suggested that it is sodium chloride contamination and not ice that is responsible for the square symmetry observed. So far, it is not clear under what conditions (if any) square ice is stable.Theoretical investigations of the stability of confined 2D ice at high lateral pressures can, in principle, help in disentangling this issue and in complementing experimental findings [3][4][5][6][7][8][9][10]. From a theoretical perspective, the prediction of square 2D ice can be traced back to Nagle's 1970's "unit model" of ice [3]. However, later atomistic force field (FF) simulations found that 2D ice prefers a buckled rhombic structure [4,5]. More recently, density functional theory (DFT) based investigations [6-9] have been performed. However, these have produced qualitatively different results depending on the precise details of the calculations and, in particular, on the choice of exchange-correlation (XC) functional. For instance, Chen et al. [7] found hexagonal and pentagonal structures to be stable phases at low pressures (Fig. 1). They also found that square ice is only stable in the GPa pressure * angelos.michaelides@ucl.ac.uk Published by the American Physical Society under the terms of the Creative Commons Attribution 4.0 International license. Further...

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“…Numerous studies have also been carried out on systems dominated by weak intermolecular forces such as Van der Waals interactions [12][13][14][15] and on adsorption phenomena 16,17 . More recently, improvements in ionic forces evaluation has led to the first successful attempt of fully QMC-based molecular dynamics simulations of liquid water 18,19 . While the statistical error can be systematically decreased down to the desired accuracy, the FS effects in a correlated framework such as QMC are considerably more delicate to deal with.…”

Section: Introductionmentioning

confidence: 99%

Exact special twist method for quantum Monte Carlo simulations

et al. 2016

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We present a systematic investigation of the special twist method introduced by Rajagopal et al. [Phys. Rev. B 51, 10591 (1995)] for reducing finite-size effects in correlated calculations of periodic extended systems with Coulomb interactions and Fermi statistics. We propose a procedure for finding special twist values which, at variance with previous applications of this method, reproduce the energy of the mean-field infinite-size limit solution within an adjustable (arbitrarily small) numerical error. This choice of the special twist is shown to be the most accurate single-twist solution for curing one-body finite-size effects in correlated calculations. For these reasons we dubbed our procedure "exact special twist" (EST). EST only needs a fully converged independent-particles or mean-field calculation within the primitive cell and a simple fit to find the special twist along a specific direction in the Brillouin zone. We first assess the performances of EST in a simple correlated model such as the 3D electron gas. Afterwards, we test its efficiency within ab initio quantum Monte Carlo simulations of metallic elements of increasing complexity. We show that EST displays an overall good performance in reducing finite-size errors comparable to the widely used twist average technique but at a much lower computational cost, since it involves the evaluation of just one wavefunction. We also demonstrate that the EST method shows similar performances in the calculation of correlation functions, such as the ionic forces for structural relaxation and the pair radial distribution function in liquid hydrogen. Our conclusions point to the usefulness of EST for correlated supercell calculations; our method will be particularly relevant when the physical problem under consideration requires large periodic cells.

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Ab initio molecular dynamics simulation of liquid water by quantum Monte Carlo

Cited by 73 publications

References 80 publications

Nuclear Quantum Effects in Water and Aqueous Systems: Experiment, Theory, and Current Challenges

Nuclear Quantum Effects in Water and Aqueous Systems: Experiment, Theory, and Current Challenges

Evidence for stable square ice from quantum Monte Carlo

Exact special twist method for quantum Monte Carlo simulations

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