English

Quantum wave packet revivals in circular billiards

Quantum Physics 2009-11-10 v1

Abstract

We examine the long-term time-dependence of Gaussian wave packets in a circular infinite well (billiard) system and find that there are approximate revivals. For the special case of purely m=0m=0 states (central wave packets with no momentum) the revival time is Trev(m=0)=8μR2/πT_{rev}^{(m=0)} = 8\mu R^2/\hbar \pi, where μ\mu is the mass of the particle, and the revivals are almost exact. For all other wave packets, we find that Trev(m0)=(π2/2)Trev(m=0)5Trev(m=0)T_{rev}^{(m \neq 0)} = (\pi^2/2) T_{rev}^{(m=0)} \approx 5T_{rev}^{(m=0)} and the nature of the revivals becomes increasingly approximate as the average angular momentum or number of m0m \neq 0 states is/are increased. The dependence of the revival structure on the initial position, energy, and angular momentum of the wave packet and the connection to the energy spectrum is discussed in detail. The results are also compared to two other highly symmetrical 2D infinite well geometries with exact revivals, namely the square and equilateral triangle billiards. We also show explicitly how the classical periodicity for closed orbits in a circular billiard arises from the energy eigenvalue spectrum, using a WKB analysis.

Keywords

Cite

@article{arxiv.quant-ph/0307020,
  title  = {Quantum wave packet revivals in circular billiards},
  author = {R. W. Robinett and S. Heppelmann},
  journal= {arXiv preprint arXiv:quant-ph/0307020},
  year   = {2009}
}

Comments

21 pages, 4 figures