Learning to Use the Force: Fitting Repulsive Potentials in Density-Functional Tight-Binding with Gaussian Process Regression

Panosetti, Chiara; Engelmann, Artur; Nemec, Lydia; Reuter, Karsten; Margraf, Johannes T.

doi:10.1021/acs.jctc.9b00975

Cited by 33 publications

(35 citation statements)

References 66 publications

(132 reference statements)

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“…The electronic parameters (in [ 26 ], only the confinement potential) were optimized by means of particle swarm optimization (PSO) [ 27 ]. In our GPrep approach, the repulsion potential was then fitted using Gaussian process regression (GPR) [ 28 ] as described in [ 26 ]. The initial parametrization in [ 26 ] did not include the Li–Li repulsion.…”

Section: Materials and Methodsmentioning

confidence: 99%

Accessing Structural, Electronic, Transport and Mesoscale Properties of Li-GICs via a Complete DFTB Model with Machine-Learned Repulsion Potential

et al. 2021

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Lithium-graphite intercalation compounds (Li-GICs) are the most popular anode material for modern lithium-ion batteries and have been subject to numerous studies—both experimental and theoretical. However, the system is still far from being consistently understood in detail across the full range of state of charge (SOC). The performance of approaches based on density functional theory (DFT) varies greatly depending on the choice of functional, and their computational cost is far too high for the large supercells necessary to study dilute and non-equilibrium configurations which are of paramount importance for understanding a complete charging cycle. On the other hand, cheap machine learning methods have made some progress in predicting, e.g., formation energetics, but fail to provide the full picture, including electrostatics and migration barriers. Following up on our previous work, we deliver on the promise of providing a complete and affordable simulation framework for Li-GICs. It is based on density functional tight binding (DFTB), which is fitted to dispersion-corrected DFT data using Gaussian process regression (GPR). In this work, we added the previously neglected lithium–lithium repulsion potential and extend the training set to include superdense Li-GICs (LiC6−x; x>0) and lithium metal, allowing for the investigation of dendrite formation, next-generation modified GIC anodes, and non-equilibrium states during fast charging processes in the future. For an extended range of structural and energetic properties—layer spacing, bond lengths, formation energies and migration barriers—our method compares favorably with experimental results and with state-of-the-art dispersion-corrected DFT at a fraction of the computational cost. We make use of this by investigating some larger-scale system properties—long range Li–Li interactions, dielectric constants and domain-formation—proving our method’s capability to bring to light new insights into the Li-GIC system and bridge the gap between DFT and meso-scale methods such as cluster expansions and kinetic Monte Carlo simulations.

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Section: Materials and Methodsmentioning

confidence: 99%

Accessing Structural, Electronic, Transport and Mesoscale Properties of Li-GICs via a Complete DFTB Model with Machine-Learned Repulsion Potential

et al. 2021

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“…A universal density functional provided by an ML model could potentially eliminate the need for exhaustively comparing different types of functionals for a given chemical problem. So far, ML has been used to generate new DFT functionals or to adjust the energy functional, bypassing the need to solve the iterative Kohn-Sham equations and accelerating simulations for the ground state 104,107,[129][130][131][132][133][134] and excited states 135 significantly. These models further promise better transferability for different types of molecular systems.…”

Section: Please Cite This Article As Doi:101063/50047760mentioning

confidence: 99%

“…Beyond that, several groups have proposed to combine established DFTB Slater-Koster parametrizations with kernel ridge regression or NN representations of the repulsive energy contributions to improve the accuracy and transferability of DFTB. 149,150 On the example of the QM7-X data set 151 , a mean absolute error of 0.5 kcal/mol could be achieved on the atomization energies of the DFTB-ML model compared to hybrid DFT reference values. 149 Future directions: We expect a vivid development regarding the tight integration of ML within electronic structure software -an approach that some package developers already pursue (e.g., in the case of entos 152 and DFTB+ 153 ).…”

Section: Please Cite This Article As Doi:101063/50047760mentioning

confidence: 99%

Perspective on integrating machine learning into computational chemistry and materials science

Westermayr

Gastegger

Schütt³

et al. 2021

The Journal of Chemical Physics

143

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Machine learning (ML) methods are being used in almost every conceivable area of electronic structure theory and molecular simulation. In particular, ML has become firmly established in the construction of highdimensional interatomic potentials. Not a day goes by without another proof of principle being published on how ML methods can represent and predict quantum mechanical properties -be they observable, such as molecular polarizabilities, or not, such as atomic charges. As ML is becoming pervasive in electronic structure theory and molecular simulation, we provide an overview of how atomistic computational modeling is being transformed by the incorporation of ML approaches. From the perspective of the practitioner in the field, we assess how common workflows to predict structure, dynamics, and spectroscopy are affected by ML. Finally, we discuss how a tighter and lasting integration of ML methods with computational chemistry and materials science can be achieved and what it will mean for research practice, software development, and postgraduate training.

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“…Several recent methodological developments, like the development of the DFTB3 method 21 and its corresponding parameterization, 22 the use of long-range corrections, 23 improvement of the description of intermolecular 24 and dispersion interactions, 25–28 have significantly increased the accuracy of the method. For parameterization, several automated schemes and schemes which utilize machine learning have been developed, 29–37 increasing the applicability of the DFTB method to different systems and problems.…”

Section: Introductionmentioning

confidence: 99%

Benchmarks of the density functional tight-binding method for redox, protonation and electronic properties of quinones

Kitheka

Redington

Zhang

et al. 2022

Phys. Chem. Chem. Phys.

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Learning to Use the Force: Fitting Repulsive Potentials in Density-Functional Tight-Binding with Gaussian Process Regression

Cited by 33 publications

References 66 publications

Accessing Structural, Electronic, Transport and Mesoscale Properties of Li-GICs via a Complete DFTB Model with Machine-Learned Repulsion Potential

Accessing Structural, Electronic, Transport and Mesoscale Properties of Li-GICs via a Complete DFTB Model with Machine-Learned Repulsion Potential

Perspective on integrating machine learning into computational chemistry and materials science

Benchmarks of the density functional tight-binding method for redox, protonation and electronic properties of quinones

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