Marc Jäger scite author profile

DScribe is a software package for machine learning that provides popular feature transformations ("descriptors") for atomistic materials simulations. DScribe accelerates the application of machine learning for atomistic property prediction by providing user-friendly, off-the-shelf descriptor implementations. The package currently contains implementations for Coulomb matrix, Ewald sum matrix, sine matrix, Many-body Tensor Representation (MBTR), Atom-centered Symmetry Function (ACSF) and Smooth Overlap of Atomic Positions (SOAP). Usage of the package is illustrated for two different applications: formation energy prediction for solids and ionic charge prediction for atoms in organic molecules. The package is freely available under the open-source Apache License 2.0.

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Machine learning hydrogen adsorption on nanoclusters through structural descriptors

Jäger

et al. 2018

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Catalytic activity of the hydrogen evolution reaction on nanoclusters depends on diverse adsorption site structures. Machine learning reduces the cost for modelling those sites with the aid of descriptors. We analysed the performance of state-of-the-art structural descriptors Smooth Overlap of Atomic Positions, Many-Body Tensor Representation and Atom-Centered Symmetry Functions while predicting the hydrogen adsorption (free) energy on the surface of nanoclusters. The 2D-material molybdenum disulphide and the alloy copper-gold functioned as test systems. Potential energy scans of hydrogen on the cluster surfaces were conducted to compare the accuracy of the descriptors in kernel ridge regression. By having recourse to data sets of 91 molybdenum disulphide clusters and 24 copper-gold clusters, we found that the mean absolute error could be reduced by machine learning on different clusters simultaneously rather than separately. The adsorption energy was explained by the local descriptor Smooth Overlap of Atomic Positions, combining it with the global descriptor Many-Body Tensor Representation did not improve the overall accuracy. We concluded that fitting of potential energy surfaces could be reduced significantly by merging data from different nanoclusters.

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Ab initio study of CO2 hydrogenation mechanisms on inverse ZnO/Cu catalysts

Reichenbach¹,

Mondal²,

Jäger

et al. 2018

Journal of Catalysis

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Chemical bonding in initial building blocks of semiconductors: Geometrical structures and optical absorption spectra of isolated CdSe2+ and Cd2Se2+ species

Jäger

Shayeghi

Klippenstein

et al. 2018

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GIGA: a versatile genetic algorithm for free and supported clusters and nanoparticles in the presence of ligands

Jäger

Johnston

2019

Nanoscale

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Marc Jäger

DScribe: Library of descriptors for machine learning in materials science

Machine learning hydrogen adsorption on nanoclusters through structural descriptors

Ab initio study of CO2 hydrogenation mechanisms on inverse ZnO/Cu catalysts

Chemical bonding in initial building blocks of semiconductors: Geometrical structures and optical absorption spectra of isolated CdSe2+ and Cd2Se2+ species

GIGA: a versatile genetic algorithm for free and supported clusters and nanoparticles in the presence of ligands

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