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Neural Network Interaction Potentials for para-Hydrogen with Flexible Molecules

Chemical Physics 2022-09-07 v2

Abstract

The study of molecular impurities in parapara-hydrogen (ppH2\rm_2) clusters is key to push forward our understanding of intra- and intermolecular interactions including their impact on the superfluid response of this bosonic quantum solvent. This includes tagging with one or very few ppH2\rm_2, the microsolvation regime, and matrix isolation. However, the fundamental coupling between the bosonic ppH2\rm_2 environment and the (ro-)vibrational motion of molecular impurities remains poorly understood. Quantum simulations can in provide the necessary atomistic insight, but very accurate descriptions of the involved interactions are required. Here, we present a data-driven approach for the generation of impuritypimpurity\cdots pH2\rm_2 interaction potentials based on machine learning techniques which retain the full flexibility of the impurity. We employ the well-established adiabatic hindered rotor (AHR) averaging technique to include the impact of the nuclear spin statistics on the symmetry-allowed rotational quantum numbers of ppH2\rm_2. Embedding this averaging procedure within the high-dimensional neural network potential (NNP) framework enables the generation of highly-accurate AHR-averaged NNPs at coupled cluster accuracy, namely CCSD(T^*)-F12a/aVTZcp in an automated manner. We apply this methodology to the water and protonated water molecules, as representative cases for quasi-rigid and highly-flexible molecules respectively, and obtain AHR-averaged NNPs that reliably describe the H2\rm _2Op\cdots pH2\rm_2 and H3\rm _3O+p^+\cdots pH2\rm_2 interactions. Using path integral simulations we show for the hydronium cation that umbrella-like tunneling inversion has a strong impact on the first and second ppH2\rm_2 microsolvation shells. The data-driven nature of our protocol opens the door to the study of bosonic ppH2\rm_2 quantum solvation for a wide range of embedded impurities.

Keywords

Cite

@article{arxiv.2206.08251,
  title  = {Neural Network Interaction Potentials for para-Hydrogen with Flexible Molecules},
  author = {Laura Durán Caballero and Christoph Schran and Fabien Brieuc and Dominik Marx},
  journal= {arXiv preprint arXiv:2206.08251},
  year   = {2022}
}

Comments

The following article has been submitted to the Journal of Chemical Physics

R2 v1 2026-06-24T11:54:01.471Z