Uncertainty quantification for classical effective potentials: an extension to <i>potfit</i>

Longbottom, Sarah; Brommer, P.E.

doi:10.1088/1361-651x/ab0d75

Cited by 18 publications

(17 citation statements)

References 33 publications

(46 reference statements)

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“…Evaluating an error or measure of confidence in a data-driven prediction like n(x) is a well studied problem [15,16]. Applications of uncertainty quantification have recently begun appearing in materials science, with some even in DFT, such as the linear model exchange correlation functional of Aldegunde et al [17][18][19][20][21]. In this work, we show that useful applications of a predictive uncertainty in n(x) can be realised for just one of many possible approaches.…”

Section: Quantifying Uncertaintymentioning

confidence: 89%

Managing uncertainty in data-derived densities to accelerate density functional theory

Pickard

Elliott

2019

J. Phys. Mater.

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Faithful representations of atomic environments and general models for regression can be harnessed to learn electron densities that are close to the ground state. One of the applications of data-derived electron densities is orbital-free density functional theory (DFT). However, extrapolations of densities learned from a training set to dissimilar structures could result in inaccurate results, which would limit the applicability of the method. Here, we show that a non-Bayesian approach can produce estimates of uncertainty which can successfully distinguish accurate from inaccurate predictions of electron density. We apply our approach to DFT where we initialise calculations with data-derived densities only when we are confident about their quality. This results in a guaranteed acceleration to selfconsistency for configurations that are similar to those seen during training and could be useful for sampling-based methods, where previous ground state densities cannot be used to initialise subsequent calculations.

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Section: Quantifying Uncertaintymentioning

confidence: 89%

Managing uncertainty in data-derived densities to accelerate density functional theory

Pickard

Elliott

2019

J. Phys. Mater.

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“…Furthermore, quantification of uncertainty due to the potential fitting reference set [57] was augmented by propagation of parametric uncertainties to MD outputs [58]. Recent efforts have focused on fitting interatomic potentials to data and subsequently quantifying the uncertainty [59]. These efforts contributed to the uncertainty quantification and potential development by providing an open source implementation of the framework proposed by Frederiksen et al [54].…”

Section: Uncertainty Quantification Approaches For MD Simulationsmentioning

confidence: 99%

“…A good measure of the confidence in the model predictions consists of evaluating the uncertainty in the effective potential. Longbottom, et al, have demonstrated this technique using three potentials for nickel: two simple pair potentials, Lennard-Jones and Morse, and a local density dependent embedded atom method potential [59]. They were successful in developing a potential ensemble fit to DFT calibration data to calculate the uncertainties in lattice constants, elastic constants and thermal expansion of nickel.…”

Section: Uncertainty Quantification Approaches For MD Simulationsmentioning

confidence: 99%

Uncertainty Quantification in Atomistic Modeling of Metals and Its Effect on Mesoscale and Continuum Modeling: A Review

Gabriel

Paulson

Duong

et al. 2020

JOM

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The design of next-generation alloys through the Integrated Computational Materials Engineering (ICME) approach relies on multi-scale computer simulations to provide thermodynamic properties when experiments are difficult to conduct. Atomistic methods such as Density Functional Theory (DFT) and Molecular Dynamics (MD) have been successful in predicting properties of never before studied compounds or phases. However, uncertainty quantification (UQ) of DFT and MD results is rarely reported due to computational and UQ methodology challenges. Over the past decade, studies have emerged that mitigate this gap. These advances are reviewed in the context of thermodynamic modeling and information exchange with mesoscale methods such as Phase Field Method (PFM) and Calculation of Phase Diagrams (CALPHAD). The importance of UQ is illustrated using properties of metals, with aluminum as an example, and highlighting deterministic, frequentist and Bayesian methodologies. Challenges facing routine uncertainty quantification and an outlook on addressing them are also presented.

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“…A typical empirical potential has between 2 and 11 parameters (rising to > 1000 for modern machine-learning potentials), and the highly nonlinear nature of the overall model necessitates quantifying the uncertainty in their choice and how this propagates to the quantities of interest. In the literature, this is usually done by employing a Bayesian framework, in which one assumes some prior probability distributions for the parameters, which are subsequently updated using available datasets originating from experiments or higher-level theories [10,21,33]. However, two main issues can potentially arise with this approach.…”

Section: Introductionmentioning

confidence: 99%

“…However, two main issues can potentially arise with this approach. Firstly, the prior distribution of each parameter is typically taken to be a Gaussian (e.g., in [10,21,33]), due to the seemingly reasonable assumption that errors in the reference dataset are independent. This may not necessarily hold true, depending on the physical constraints present in the model, such as, for example, the fact that some parameters have positive values.…”

Section: Introductionmentioning

confidence: 99%

A stochastic framework for atomistic fracture

Buze¹,

Woolley²,

Mihai³

2021

Preprint

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We present a stochastic modeling framework for atomistic propagation of a Mode I surface crack, with atoms interacting according to the Lennard-Jones interatomic potential at zero temperature. Specifically, we invoke the Cauchy-Born rule and the maximum entropy principle to infer probability distributions for the parameters of the interatomic potential. We then study how uncertainties in the parameters propagate to the quantities of interest relevant to crack propagation, namely, the critical stress intensity factor and the lattice trapping range. For our numerical investigation, we rely on an automated version of the so-called numerical-continuation enhanced flexible boundary (NCFlex) algorithm.

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Uncertainty quantification for classical effective potentials: an extension to potfit

Cited by 18 publications

References 33 publications

Managing uncertainty in data-derived densities to accelerate density functional theory

Managing uncertainty in data-derived densities to accelerate density functional theory

Uncertainty Quantification in Atomistic Modeling of Metals and Its Effect on Mesoscale and Continuum Modeling: A Review

A stochastic framework for atomistic fracture

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