Abstract: Methods and systems of altering optical reflection via dynamic control of an ultrasonic/acoustic guided wave field in an acousto-optical wave conductor are described. Ultrasonic/acoustic waves transmitted by an acousto-optical wave conductor are used to modify the ability of the acousto-optical wave conductor to propagate light waves via the acousto-optical wave conductor when a light beam impinges onto one surface of the acousto-optical wave conductor. A one-way optical device may be produced by using a dynamic tuning approach to modify the sound field via mode and frequency choice (and possibly beam focusing and steering as well) in order to produce special light reflection and transmission effects. Oscillations in stress (and mass density) along the acousto-optical wave conductor and possibly across the thickness of the acousto-optical wave conductor may serve as a special acousto-optic Bragg diffraction grating that alters the nonspecular reflection of light.

Abstract: Methods and systems of altering optical reflection via dynamic control of an ultrasonic/acoustic guided wave field in an acousto-optical wave conductor are described. Ultrasonic/acoustic waves transmitted by an acousto-optical wave conductor are used to modify the ability of the acousto-optical wave conductor to propagate light waves via the acousto-optical wave conductor when a light beam impinges onto one surface of the acousto-optical wave conductor. A one-way optical device may be produced by using a dynamic tuning approach to modify the sound field via mode and frequency choice (and possibly beam focusing and steering as well) in order to produce special light reflection and transmission effects. Oscillations in stress (and mass density) along the acousto-optical wave conductor and possibly across the thickness of the acousto-optical wave conductor may serve as a special acousto-optic Bragg diffraction grating that alters the nonspecular reflection of light.

Abstract: A method of forming a sculptured thin film on a surface includes rotating the surface and depositing a sculptured thin film comprised of a polymer on the surface to form submicron or nanoscale wires during the step of rotating. The submicron wires may be columnar, helically columnar, chevron shaped, chiral shaped, distinct or interwoven. The depositing step may involve pyrolizing the polymer into a vapor of monomers, directing the vapor of monomers towards the surface while rotating the surface, and polymerizing the monomers on the surface. The surface may be incorporated into biomedical device or other biological application where the sculptured thin film is biocompatible and bioactive and adapted for a biological use.

Abstract: A method of forming a sculptured thin film on a surface includes rotating the surface and depositing a sculptured thin film comprised of a polymer on the surface to form submicron wires during the step of rotating. The submicron wires may be columnar, helically columnar, chevron shaped, chiral shaped, distinct or interwoven. The depositing step may involve pyrolizing the polymer into a vapor of monomers, directing the vapor of monomers towards the surface while rotating the surface, and polymerizing the monomers on the surface. The surface may be incorporated into biomedical device or other biological application where the sculptured thin film is biocompatible and bioactive and adapted for a biological use.