Femtosecond-laser generation of self-organized bubble patterns in fused silica

By continuously scanning a femtosecond laser beam across a fused silica specimen, we demonstrate the formation of self-organized bubbles buried in the material. Rather than using high intensity pulses and high numerical aperture to induce explosions in the material, here bubbles form as a consequence of cumulative energy deposits. We observe a transition between chaotic and self-organized patterns at high scanning rate (above 10 mm/s). Through modeling the energy exchange, we outline the similarities of this phenomenon with other non-linear dynamical systems. Furthermore, we demonstrate with this method the high-speed writing of two- and three-dimensional bubble "crystals" in bulk silica. (C)2011 Optical Society of America

Femtosecond-laser generation of self-organized bubble patterns in fused silica

On the interaction of femtosecond laser pulses with layered dielectric materials

Femtosecond laser-induced modifications and self-organization in complex glass systems

In situ monitoring of femtosecond laser-induced modifications in dielectrics

On the interaction of femtosecond laser pulses with layered dielectric materials

In situ monitoring of femtosecond laser-induced modifications in dielectrics

Femtosecond laser-induced modifications and self-organization in complex glass systems