Statistical properties of spectral fluctuations for a quantum system with infinitely many components

TL;DR

This paper analyzes the spectral fluctuations of a classically integrable quantum system with infinitely many components, deriving the level number variance and comparing it to Poisson statistics, revealing deviations due to component accumulation.

Contribution

It extends the Berry-Robnik approach to systems with infinitely many components, deriving the level number variance and identifying deviations from Poisson behavior.

Findings

The level number variance (LNV) is derived for infinitely many components.

The LNV slope exceeds Poisson statistics when components accumulate.

Results align with semiclassical periodic-orbit theory predictions.

Abstract

Extending the idea formulated in Makino {\it{et al}}[Phys.Rev.E {\bf{67}},066205], that is based on the Berry--Robnik approach [M.V. Berry and M. Robnik, J. Phys. A {\bf{17}}, 2413], we investigate the statistical properties of a two-point spectral correlation for a classically integrable quantum system. The eigenenergy sequence of this system is regarded as a superposition of infinitely many independent components in the semiclassical limit. We derive the level number variance (LNV) in the limit of infinitely many components and discuss its deviations from Poisson statistics. The slope of the limiting LNV is found to be larger than that of Poisson statistics when the individual components have a certain accumulation. This property agrees with the result from the semiclassical periodic-orbit theory that is applied to a system with degenerate torus actions[D. Biswas, M.Azam,and S.V.Lawande, Phys. Rev. A {\bf 43}, 5694].