How chaotic is the stadium billiard? A semiclassical analysis

The impression gained from the literature published to date is that the spectrum of the stadium billiard can be adequately described, semiclassically, by the Gutzwiller periodic orbit trace formula together with a modified treatment of the marginally stable family of bouncing-ball orbits. I show that this belief is erroneous. The Gutzwiller trace formula is not applicable for the phase-space dynamics near the bouncing-ball orbits. Unstable periodic orbits close to the marginally stable family in phase space cannot be treated as isolated stationary phase points when approximating the trace of the Green's function. Semiclassical contributions to the trace show an -dependent transition from hard chaos to integrable behaviour for trajectories approaching the bouncing-ball orbits. A whole region in phase space surrounding the marginal stable family acts, semiclassically, like a stable island with boundaries being explicitly -dependent. The localized bouncing-ball states found in the billiard derive from this semiclassically stable island. The bouncing-ball orbits themselves, however, do not contribute to individual eigenvalues in the spectrum. An EBK-like quantization of the regular bouncing-ball eigenstates in the stadium can be derived. The stadium billiard is thus an ideal model for studying the influence of almost regular dynamics near marginally stable boundaries on quantum mechanics. The behaviour is generically found at the border of classically stable islands in systems with a mixed phase-space structure.