Quantum chaos in a deformable billiard: Applications to quantum dots

TL;DR

This study numerically analyzes energy levels and wavefunctions of deformable quantum billiards, revealing how classical chaos influences quantum properties relevant to quantum dots, with results aligning with random-matrix theory in chaotic regimes.

Contribution

It provides a detailed numerical investigation of quantum chaos in deformable billiards, connecting classical dynamics with quantum statistical properties in quantum dots.

Findings

Statistical properties match random-matrix theory in chaotic regimes.

Level-width distribution follows chi-squared distribution in fully chaotic systems.

Energy-level correlations agree with disordered system models.

Abstract

We perform a detailed numerical study of energy-level and wavefunction statistics of a deformable quantum billiard focusing on properties relevant to semiconductor quantum dots. We consider the family of Robnik billiards generated by simple conformal maps of the unit disk; the shape of this family of billiards may be varied continuously at fixed area by tuning the parameters of the map. The classical dynamics of these billiards is well-understood and this allows us to study the quantum properties of subfamilies which span the transition from integrability to chaos as well as families at approximately constant degree of chaoticity (Kolmogorov entropy). In the regime of hard chaos we find that the statistical properties of interest are well-described by random-matrix theory and completely insensitive to the particular shape of the dot. However in the nearly-integrable regime non-universal behavior is found. Specifically, the level-width distribution is well-described by the predicted $\chi^2$ distribution both in the presence and absence of magnetic flux when the system is fully chaotic; however it departs substantially from this behavior in the mixed regime. The chaotic behavior corroborates the previously predicted behavior of the peak-height distribution for deformed quantum dots. We also investigate the energy-level correlation functions which are found to agree well with the behavior calculated for quasi-zero-dimensional disordered systems.