Intrinsic stickiness in open integrable billiards: tiny border effects

Abstract

Rounding border effects at the escape point of open integrable billiards are analyzed via the escape times statistics and emission angles. The model is the rectangular billiard and the shape of the escape point is assumed to have a semicircular form. Stickiness and self-similar structures for the escape times and emission angles are generated inside "backgammon" like stripes of initial conditions. These stripes are born at the boundary between two different emission angles but same escape times. As the rounding effects increase, backgammon stripes start to overlap and the escape times statistics obeys the power law decay and anomalous diffusion is expected. Tiny rounded borders (around 0.1\% from the whole billiard size) are shown to be sufficient to generate the sticky motion, while borders larger than 10\% are enough to produce escape times with chaotic decay.