Exact treatment of rotation-induced modifications in two-dimensional quantum rings

• URL: http://arxiv.org/abs/2506.23300v1
• Date: Sun, 29 Jun 2025 15:39:36 GMT
• Title: Exact treatment of rotation-induced modifications in two-dimensional quantum rings
• Authors: Carlos Magno O. Pereira, Frankbelson dos S. Azevedo, Edilberto O. Silva,
• Abstract summary: We investigate the influence of rotation on the Fermi energy, magnetization, and persistent current in two-dimensional quantum rings.<n>We numerically explore how variations in angular velocity affect the Fermi energy, magnetization, and persistent current.
• Score: 0.0
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: We investigate the influence of rotation on the Fermi energy, magnetization, and persistent current in two-dimensional quantum rings. Using the Tan-Inkson confinement potential and incorporating rotational effects through a non-inertial coupling, we derive analytical expressions for the energy levels and examine the modifications induced by rotation. We then numerically explore how variations in angular velocity affect the Fermi energy, magnetization, and persistent current. Our results show that rotation has a significant impact on these physical properties, underscoring the importance of considering rotational effects in quantum ring systems. This suggests that rotation could serve as a control parameter in the development of new mesoscopic devices, without the need for additional fields or geometric modifications.

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