Classical Nuclear Motion: Comparison to Approaches with Quantum Mechanical Nuclear Motion

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Authors

  • Irmgard Frank

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Original languageEnglish
Pages (from-to)11 - 21
Number of pages11
JournalHydrogen
Volume4
Issue number1
Publication statusPublished - 29 Dec 2022

Abstract

Ab initio molecular dynamics combines a classical description of nuclear motion with a density-functional description of the electronic cloud. This approach nicely describes chemical reactions. A possible conclusion is that a quantum mechanical description of nuclear motion is not needed. Using Occam’s razor, this means that, being the simpler approach, classical nuclear motion is preferable. In this paper, it is claimed that nuclear motion is classical, and this hypothesis will be tested in comparison to methods with quantum mechanical nuclear motion. In particular, we apply ab initio molecular dynamics to two photoreactions involving hydrogen. Hydrogen, as the lightest element, is often assumed to show quantum mechanical tunneling. We will see that the classical picture is fully sufficient. The quantum mechanical view leads to phenomena that are difficult to understand, such as the entanglement of nuclear motion. In contrast, it is easy to understand the simple classical picture which assumes that nuclear motion is steady and uniform unless a force is acting. Of course, such a hypothesis must be verified for many systems and phenomena, and this paper is one more step in this direction.

Keywords

    Car–Parrinello molecular dynamics, chemical reactions, classical nuclear motion, photoreactions

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Cite this

Classical Nuclear Motion: Comparison to Approaches with Quantum Mechanical Nuclear Motion. / Frank, Irmgard.
In: Hydrogen, Vol. 4, No. 1, 29.12.2022, p. 11 - 21.

Research output: Contribution to journalArticleResearchpeer review

Frank I. Classical Nuclear Motion: Comparison to Approaches with Quantum Mechanical Nuclear Motion. Hydrogen. 2022 Dec 29;4(1):11 - 21. doi: 10.3390/hydrogen4010002
Frank, Irmgard. / Classical Nuclear Motion : Comparison to Approaches with Quantum Mechanical Nuclear Motion. In: Hydrogen. 2022 ; Vol. 4, No. 1. pp. 11 - 21.
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