Energy shift of H-atom electrons due to Gibbons-Hawking thermal bath
Miroslav Pardy
TL;DR
This paper calculates how the energy levels of hydrogen atom electrons are affected by a Gibbons-Hawking thermal bath using non-relativistic quantum mechanics, revealing shifts caused by the thermal environment.
Contribution
It introduces a novel calculation of hydrogen atom energy shifts due to the Gibbons-Hawking thermal bath within a non-relativistic quantum framework.
Findings
Energy levels of H-atom electrons are shifted by the Gibbons-Hawking thermal bath.
The magnitude of the energy shift depends on the properties of the thermal bath.
The study provides a theoretical basis for understanding quantum systems in curved spacetime environments.
Abstract
The electromagnetic shift of energy levels of H-atom electrons is determined by calculating an electron coupling to the Gibbons-Hawking electromagnetic field thermal bath. Energy shift of electrons in H-atom is determined in the framework of the non-relativistic quantum mechanics.
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Taxonomy
TopicsQuantum Electrodynamics and Casimir Effect · Cosmology and Gravitation Theories · Solar and Space Plasma Dynamics