Abstract
We investigate the gravitational effect on Landau levels. We show that the familiar infinite Landau degeneracy of the energy levels of a quantum particle moving inside a uniform and constant magnetic field is removed by the interaction of the particle with a gravitational field. Two independent approaches are used to solve the relevant Schrödinger equation within the Newtonian approximation. It is found that both approaches yield qualitatively similar results within their respective approximations. With the goal of clarifying some results found in the literature concerning the use of a third independent approach for extracting the quantization condition based on a similar differential equation, we show that such an approach cannot yield a general and yet consistent result. We point out to the more accurate, but impractical, way to use such an approach; a way which does in principle yield a consistent quantization condition. We discuss how our results could be used to contribute in a novel way to the existing methods for testing gravity at the tabletop experiments level as well as at the astrophysical observational level by deriving the corrections brought by Yukawa-like and power-law deviations from the inverse-square law. The full relativistic regime is also examined in detail.
Highlights
We have studied the effect of the gravitational field of a spherical mass on a charged particle inside a uniform and constant magnetic field
We started from the full Schwarzschild metric and derived Equation (14) that describes the dynamics of the particle for both laboratory-based experiments and astrophysical level observations
We found that the infinite Landau degeneracy is removed as the Landau orbitals of the same Landau level split in energy
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Many of the investigations conducted in the past were focused on the more modest attempt to observe the effect of gravity on a quantum particle by studying, more noticeably, the behavior of cold neutrons inside a gravitational field [1,2,3,4,5,6]. [22], based on general grounds, that Landau levels are split under the effect of an external potential which is monotonic in the radial distance along the plane perpendicular to the magnetic field This does not, contradict what was found in Ref. [23], the gravitational influence on the quantum Hall effect is due to the splitting of Landau levels caused by the potential gradient of gravity in the case of. Appendix A is devoted to a detailed derivation of the various mathematical formulas needed in the text
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