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  Predicting the electronic density response of condensed-phase systems to electric field perturbations

Lewis, A., Lazzaroni, P., & Rossi, M. (2023). Predicting the electronic density response of condensed-phase systems to electric field perturbations. The Journal of Chemical Physics, 159(1): 014103. doi:10.1063/5.0154710.

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Datensatz-Permalink: https://hdl.handle.net/21.11116/0000-000D-752D-E Versions-Permalink: https://hdl.handle.net/21.11116/0000-000D-752E-D
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014103_1_5.0154710.pdf (Verlagsversion), 6MB
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Supplementary Material: contains details of the optimization of the dummy atom parameters, the convergence of the machine-learning models with respect to the number of reference environments, a description of additional machine-learning parameters, details of the auxiliary basis employed, and an analysis of the origin of the error in the polarizability or dielectric susceptibility derived from a predicted density response.
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https://arxiv.org/abs/2304.09057 (Preprint)
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 Urheber:
Lewis, A.1, Autor
Lazzaroni, P.1, 2, Autor           
Rossi, M.1, Autor
Affiliations:
1Simulations from Ab Initio Approaches, Theory Department, Max Planck Institute for the Structure and Dynamics of Matter, Max Planck Society, ou_3185035              
2International Max Planck Research School for Ultrafast Imaging & Structural Dynamics (IMPRS-UFAST), Max Planck Institute for the Structure and Dynamics of Matter, Max Planck Society, ou_2266714              

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 Zusammenfassung: We present a local and transferable machine-learning approach capable of predicting the real-space density response of both molecules and periodic systems to homogeneous electric fields. The new method, Symmetry-Adapted Learning of Three-dimensional Electron Responses (SALTER), builds on the symmetry-adapted Gaussian process regression symmetry-adapted learning of three-dimensional electron densities framework. SALTER requires only a small, but necessary, modification to the descriptors used to represent the atomic environments. We present the performance of the method on isolated water molecules, bulk water, and a naphthalene crystal. Root mean square errors of the predicted density response lie at or below 10% with barely more than 100 training structures. Derived polarizability tensors and even Raman spectra further derived from these tensors show good agreement with those calculated directly from quantum mechanical methods. Therefore, SALTER shows excellent performance when predicting derived quantities, while retaining all of the information contained in the full electronic response. Thus, this method is capable of predicting vector fields in a chemical context and serves as a landmark for further developments.

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Sprache(n): eng - English
 Datum: 2023-04-152023-06-132023-07-052023-07-03
 Publikationsstatus: Erschienen
 Seiten: -
 Ort, Verlag, Ausgabe: -
 Inhaltsverzeichnis: -
 Art der Begutachtung: Expertenbegutachtung
 Identifikatoren: arXiv: 2304.09057
DOI: 10.1063/5.0154710
 Art des Abschluß: -

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Projektname : A.M.L. acknowledges partial support from the Alexander von Humboldt Foundation. P.L. and M.R. acknowledge support through the Lise Meitner Program of the Max Planck Society and the UFAST International Max Planck Research School.
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Quelle 1

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Titel: The Journal of Chemical Physics
  Kurztitel : J. Chem. Phys.
Genre der Quelle: Zeitschrift
 Urheber:
Affiliations:
Ort, Verlag, Ausgabe: Woodbury, N.Y. : American Institute of Physics
Seiten: - Band / Heft: 159 (1) Artikelnummer: 014103 Start- / Endseite: - Identifikator: ISSN: 0021-9606
CoNE: https://pure.mpg.de/cone/journals/resource/954922836226