<i>Ab initio</i> potential-energy surfaces for complex, multichannel systems using modified novelty sampling and feedforward neural networks

Raff, Lionel M.; Malshe, M.; Hagan, Martin T.; Doughan, D. I.; Rockley, Mark G.; Komanduri, R.

doi:10.1063/1.1850458

Cited by 146 publications

(160 citation statements)

References 82 publications

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“…Neural networks have also been used in combination with QMC to provide information of quantum phase transitions [19][20][21] , topological states 22-25 , manybody localization 21,26 and entanglement properties 27 . Furthermore, neural networks are useful to fit functional forms for potential energy surfaces which are then used in subsequent simulations 28 . In contrast to the situations described above, where DQMC is applied to tight-binding Hamiltonians and the energy scales U, t, T, µ are unambiguously known, in these studies the network is used to avoid complicated and somewhat arbitrary fits to the functional form of the potential energy, allowing for more robust molecular dynamics simulations.…”

Section: Introductionmentioning

confidence: 99%

Principal component analysis for fermionic critical points

Costa

Bai

et al. 2017

Phys. Rev. B

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We use determinant Quantum Monte Carlo (DQMC), in combination with the principal component analysis (PCA) approach to unsupervised learning, to extract information about phase transitions in several of the most fundamental Hamiltonians describing strongly correlated materials. We first explore the zero temperature antiferromagnet to singlet transition in the Periodic Anderson Model, the Mott insulating transition in the Hubbard model on a honeycomb lattice, and the magnetic transition in the 1/6-filled Lieb lattice. We then discuss the prospects for learning finite temperature superconducting transitions in the attractive Hubbard model, for which there is no sign problem. Finally, we investigate finite temperature CDW transitions in the Holstein model, where the electrons are coupled to phonon degrees of freedom. We examine the different behaviors associated with providing Hubbard-Stratonovich auxiliary fields configurations on both the entire space-time lattice and on a single imaginary time slice, or other quantities, such as equal-time Green's and pair-pair correlation functions.

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Section: Introductionmentioning

confidence: 99%

Principal component analysis for fermionic critical points

Costa

Bai

et al. 2017

Phys. Rev. B

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“…14 Over the past two decades, they have been applied to fit many high-dimensional PESs for isolated molecules and moleculesurface systems. [15][16][17][18][19][20][21][22][23] Recently, we reported a very accurate global PES for the H 2 +OH ↔ H 2 O+H reaction based on ∼17 000 ab initio points calculated at UCCSD(T)-F12/augcc-pVTZ level of theory. 24 Various tests revealed that the new surface is considerably more smooth and accurate than the existing YZCL2 and XXZ surfaces, 25,26 representing the best available potential energy surface for the OH 3 system.…”

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confidence: 99%

“…17 Then we started to perform NN fitting and carried out extensive quasi classical trajectory (QCT) calculations on the fitted PES to generate more molecular configurations. New data points were selected from generated molecular configurations by using a selection scheme originally proposed by Behler,22,24 and had their ab initio energies calculated, added to the data set.…”

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confidence: 99%

Communication: An accurate global potential energy surface for the OH + CO → H + CO2 reaction using neural networks

Chen

Xu²,

Zhang³

2013

The Journal of Chemical Physics

100

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We report a new global potential energy surface of the HOCO system based on the F12 correction of unrestricted coupled-cluster with singles doubles and approximative triples using the augmented correlation-consistent polarized valence triple-zeta basis set (UCCSD(T)-F12/AVTZ), fitted by using the neural networks. Quantum dynamics calculations confirmed the satisfactory convergence of surface with respect to the number of data points and fitting process. It is found that the total reaction probabilities and complex-formation probabilities obtained on the present surface differ considerably with those obtained on the potential energy surface recently reported by Li et al. [J. Chem. Phys. 136, 041103 (2012)]10.1063/1.3680256. Various comparisons revealed that the present surface is substantially more accurate than that surface, representing the best available potential energy surface for this benchmark complex-forming four-atom system.

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“…On the other hand, the total number of training structures should be as small as possible not only to avoid time-consuming reference calculations but also to keep the optimization process efficient. A systematic way to generate the training data for systems of arbitrary dimensionality is to employ MD tra-jectories to sample relevant configurations [28,57,76]. First, based on a set of initial training structures a preliminary NN potential is constructed and used to perform MD simulations.…”

Section: Construction Of the Reference Setmentioning

confidence: 99%

“…NNs have been used for about two decades to construct PESs for a number of different systems and several reviews have been published [22][23][24][25]. Most of these NN potentials, however, are restricted to small molecules [26][27][28][29][30][31][32] or small molecules interacting with frozen metal surfaces [33][34][35][36][37][38]. Only a few potentials for higher-dimensional systems exist, which aim to describe the properties of solids [39,40].…”

Section: Introductionmentioning

confidence: 99%

A Full-Dimensional Neural Network Potential-Energy Surface for Water Clusters up to the Hexamer

Morawietz

Behler

2013

Zeitschrift Für Physikalische Chemie

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Water clusters have attracted a lot of attention as prototype systems to study hydrogen bonded molecular aggregates but also to gain deeper insights into the properties of liquid water, the solvent of life. All these studies depend on an accurate description of the atomic interactions and countless potentials have been proposed in the literature in the past decades to represent the potential-energy surface (PES) of water. Many of these potentials employ drastic approximations like rigid water monomers and fixed point charges, while on the other hand also several attempts have been made to derive very accurate PESs by fitting data obtained in high-level electronic structure calculations. In recent years artificial neural networks (NNs) have been established as a powerful tool to construct high-dimensional PESs of a variety of systems, but to date no full-dimensional NN PES for water has been reported. Here, we present NN potentials for water clusters containing two to six water molecules trained to density functional theory (DFT) data employing two different exchange-correlation functionals, PBE and RPBE. In contrast to other potentials fitted to first principles data, these NN potentials are not based on a truncated many-body expansion of the energy but consider the interactions between all water molecules explicitly. For both functionals an excellent agreement with the underlying DFT calculations has been found with binding energy errors of only about 1%.

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Ab initio potential-energy surfaces for complex, multichannel systems using modified novelty sampling and feedforward neural networks

Cited by 146 publications

References 82 publications

Principal component analysis for fermionic critical points

Principal component analysis for fermionic critical points

Communication: An accurate global potential energy surface for the OH + CO → H + CO2 reaction using neural networks

A Full-Dimensional Neural Network Potential-Energy Surface for Water Clusters up to the Hexamer

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