Computational inverse design of non-intuitive illumination patterns to maximize optical force or torque

Author(s)

Lee, Yoonkyung E.; Miller, Owen D.; Reid, McMahon Thomas Homer; Johnson, Steven G; Fang, Xuanlai

Abstract

This paper aims to maximize optical force or torque on arbitrary micro- and nanoscale objects using numerically optimized structured illumination. By developing a numerical framework for computer-automated design of 3d vector-field illumination, we demonstrate a 20-fold enhancement in optical torque per intensity over circularly polarized plane wave on a model plasmonic particle. The nonconvex optimization is efficiently performed by combining a compact cylindrical Bessel basis representation with a fast boundary element method and a standard derivative-free, local optimization algorithm. We analyze the optimization results for 2000 random initial configurations, discuss the tradeoff between robustness and enhancement, and compare the different effects of multipolar plasmon resonances on enhancing force or torque. All results are obtained using open-source computational software available online.

Date issued

2017-03

URI

http://hdl.handle.net/1721.1/108082

Department

Massachusetts Institute of Technology. Department of Mathematics
Massachusetts Institute of Technology. Department of Mechanical Engineering

Journal

Optics Express

Publisher

Optical Society of America

Citation

Lee, Yoonkyung E. et al. “Computational Inverse Design of Non-Intuitive Illumination Patterns to Maximize Optical Force or Torque.” Optics Express 25.6 (2017): 6757.

Version: Author's final manuscript

ISSN

1094-4087