Molecular excited states through a machine learning lens

Dral, Pavlo O.; Barbatti, Mario

doi:10.1038/s41570-021-00278-1

Cited by 144 publications

(148 citation statements)

References 271 publications

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“…Owing to its generalization capabilities and fast prediction on unseen data, MLPs can be explored to accelerate minimum-energy [10][11][12][13][14][15] and transition-state structure search, 13,16,17 vibrational analysis, 18-21 absorption 22,23 and emission spectra simulation, 24 reaction 13,25,26 and structural transition exploration, 27 and ground- [3][4][5][6][7][8][9] and excitedstate dynamics propagation. 28,29 A blessing and a curse of ML is that it is possible to design, for all practical purposes, an infinite number of MLP models that can describe a molecular PES. These MLP models are usually built from two main components: the ML algorithm and its input X, the molecular descriptor.…”

Section: Introductionmentioning

confidence: 99%

Choosing the right molecular machine learning potential

et al. 2021

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Section: Introductionmentioning

confidence: 99%

Choosing the right molecular machine learning potential

et al. 2021

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“…Owing to its generalization capabilities and fast prediction on unseen data, MLPs can be explored to accelerate minimum-energy [10][11][12][13][14][15] and transition-state structure search, 13,16,17 vibrational analysis, 18-21 absorption 22,23 and emission spectra simulation, 24 reaction 13, 25,26 and structural transition exploration, 27 and ground- [3][4][5][6][7][8][9] and excitedstate dynamics propagation. 28,29 A blessing and a curse of ML is that it is possible to design, for all practical purposes, an infinite number of MLP models that can describe a molecular PES. These MLP models are usually built from two main components: the ML algorithm and its input X, the molecular descriptor.…”

Section: Introductionmentioning

confidence: 99%

Choosing the right molecular machine learning potential

Pinheiro

Ferré

et al. 2021

Preprint

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Quantum-chemistry simulations based on potential energy surfaces of molecules provide invaluable insight into the physicochemical processes at the atomistic level and yield such important observables as reaction rates and spectra. Machine learning potentials promise to significantly reduce the computational cost and hence enable otherwise unfeasible simulations. However, the surging number of such potentials begs the question of which one to choose or whether we still need to develop yet another one. Here, we address this question by evaluating the performance of popular machine learning potentials in terms of accuracy and computational cost. In addition, we deliver structured information for non-specialists in machine learning to guide them through the maze of acronyms, recognize each potential's main features, and judge what they could expect from each one.

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“…3, existing atomistic ML packages such as AMP, 155 sGDML 156 or SchNet-Pack 45,121 could be interfaced with electronic structure packages that heavily expose internal routines (e.g., FHIaims, 157 PSI4, 158 or PySCF 159 ) and be used alongside dynamics packages such as i-Pi 160 and SHARC, 161,162 as well as algebra and electronic structure libraries such as ELSI 2 and ESL. 1 The structure generation, workflow and parser tool Atomic Simulation Environment (ASE) 163 is for example already interfaced with the above examples of AMP and SchNetPack. This could also involve a closer integration with existing data repositories such as NO-MAD, 164,165 the Materials Project, 164,165 the MolSSI QC Archive 166 or the Quantum Machine repository.…”

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

confidence: 99%

“…Algorithms for molecular geometry optimization, efficient molecular dynamics simulations, and electronic structure calculations perform highly specialized tasks while being massively scalable and parallelized across a diverse range of hardware architectures. 1,2 Simultaneously, PhD graduates in the field have been trained to be expert users of existing and developers of new simulation workflows. This is the status quo at the time when machine learning (ML) methods enter the stage.…”

Section: Introductionmentioning

confidence: 99%

“…The application of ML to atomistic simulation and electronic structure theory has been developing rapidly since its earliest works in a modern context. [3][4][5][6][7][8][9][10][11] A number of excellent reviews have recently been written to a) Electronic mail: r.maurer@warwick.ac.uk highlight progress in various contexts including the role of ML in catalyst design, 12,13 in the development of forcefields and interatomic potentials for ground state properties [14][15][16][17][18][19] and excited states, [20][21][22] in quantum chemistry, 23,24 in finding solutions to the Schrödinger equation, 25 and the role of unsupervised learning in atomistic simulation 26 (see Table I for a non-exhaustive list).…”

Section: Introductionmentioning

confidence: 99%

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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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Molecular excited states through a machine learning lens

Cited by 144 publications

References 271 publications

Choosing the right molecular machine learning potential

Choosing the right molecular machine learning potential

Choosing the right molecular machine learning potential

Perspective on integrating machine learning into computational chemistry and materials science

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