Confinement Effects of External Fields and Topological Defect on Hydrogen Atom in a Quantum-plasma Environment

TL;DR

This paper investigates how external magnetic fields, Aharonov-Bohm flux, and topological defects influence the energy states of a hydrogen atom in a quantum plasma, revealing combined effects that significantly alter atomic confinement.

Contribution

It introduces a comprehensive analysis of combined external field and topological defect effects on hydrogen atoms in quantum plasmas, highlighting their joint impact on atomic energy levels.

Findings

Joint effects of fields and defects are highly attractive.

Combined effects significantly alter bound state energies.

Magnetic field acts as a control parameter.

Abstract

This study looks at the confinement effects of Aharonov-Bohm (AB) flux and magnetic fields, as well as topological defects in a quantum plasma, on the hydrogen atom. The joint effects show that the system is extremely attractive. Furthermore, as we've shown, the joint effect of the fields is greater than the sum of the individual effects, resulting in a significant change in the system's bound state energy. The magnetic field can be used as a control parameter or booster, whereas the topological defect and AB field are needed to hold the hydrogen atom in quantum plasmas at a low energy. The findings of our research may be extended to atomic structure and plasma collisions.