Photothermal Optical Beam Steering Using Large Deformation Multi-Layer Thin Film Structures

Overview

Journal Micromachines (Basel)

Publisher MDPI

Date 2021 Apr 30

PMID 33919730

Authors

Harris J Hall

Sean McDaniel

Piyush Shah

David Torres

Jose Figueroa

LaVern Starman

Affiliations

Soon will be listed here.

Abstract

Photothermal actuation of microstructures remains an active area of research for microsystems that demand electrically isolated, remote, on-chip manipulation. In this study, large-deformation structures constructed from thin films traditional to microsystems were explored through both simulation and experiment as a rudimentary means to both steer and shape an incident light beam through photothermal actuation. A series of unit step infrared laser exposures were applied at increasing power levels to both uniformly symmetric and deliberately asymmetric absorptive structures with the intent of characterizing the photothermal tilt response. The results indicate that a small angle (<4° at ~74 W/cm) mechanical tilt can be instantiated through central placement of an infrared beam, although directional control appears highly sensitive to initial beam placement. Greater responsivity (up to ~9° mechanical tilt at ~54 W/cm) and gross directional control was demonstrated with an asymmetrical absorptive design, although this response was accompanied by a large amount (~5-10°) of mechanical tilt burn-in and drift. Rigorous device cycling remains to be explored, but the results suggest that these structures, and those similar in construction, can be further matured to achieve controllable photoactuation suitable for optical beam control or other applications.

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