Influence of rotation on the electronic states, magnetization and persistent current in 1D quantum ring

TL;DR

This paper investigates how rotation affects the energy levels, persistent current, and magnetization of a quantum particle in a 1D ring under a magnetic field, highlighting inertial effects in quantum systems.

Contribution

It provides a theoretical analysis of rotational effects on quantum states, persistent current, and magnetization in a 1D quantum ring, extending understanding of inertial influences in quantum mechanics.

Findings

Rotation shifts energy levels of the quantum ring.

Persistent current and magnetization are modified by rotational effects.

Temperature influences the extent of rotational impacts on quantum properties.

Abstract

Inertial effects can affect several properties of physical systems. In particular, in the context of quantum mechanics, such effects have been studied in diverse contexts. In this paper, starting from the Schr\"{o}dinger equation for a rotating frame, we describe the influence of rotation on the energy levels of a quantum particle constrained to a one-dimensional ring in the presence of a uniform magnetic field. We also investigate how the persistent current and the magnetization in the ring are influenced by temperature and rotating effects.