Evolution of surface relief gratings in As20Se80 amorphous chalcogenide films under laser illumination

Variation of grating amplitudes on a surface of amorphous chalcogenide films (ACF) As20Se80 has been studied under illumination by a band-gap light with the purpose to understand mechanism of photo-induced (PI) mass transfer. After holographic recording of surface relief gratings (SRGs) of various periods. (from 3 to 15 mu m) they were illuminated by a diode laser (lambda = 660 nm) and their profile variation was analyzed using optical microscopy, atomic force microscopy, light scattering, and optical profilometry. The SRGs with Lambda < 8 mu m exponentially flattened with time of illumination, whereas amplitudes of the SRGs with Lambda > 8 mu m exponentially grew. Theoretical analysis of the kinetics of PI mass transfer shows that the SRG profile variation occurs by bulk diffusion of As and Se atoms as a result of competition between capillary forces and electrostatic forces created by redistribution of electrons and holes generated by light. Our theory predicts both flattening and growth of the SRG amplitudes under uniform light illumination. The PI diffusion coefficients have been estimated both from the flattening kinetics of the SRG amplitude and from its growth and found to be in good agreement with the theory. It is also observed that the profile evolution is accompanied by dewetting of ACFs and roughening of the initial SRGs.

Automated summary

The variation of grating amplitudes on the surface of amorphous chalcogenide films (ACF) As20Se80 has been studied under illumination, revealing that the amplitudes of small-period gratings exponentially decrease with time while those of large-period gratings exponentially increase. This study provides insights into the mechanism of photo-induced mass transfer, which involves the competition between capillary and electrostatic forces in the diffusion of As and Se atoms.