Application of Optical Forces in Microphotonic Systems

Abstract

Optical forces represent an exciting new approach for manipulating microphotonic devices. In this thesis, the overall goal is to invent and demonstrate novel microphotonic device functionalities based on optical forces. There are two major tasks. One is to explore how optical forces can be used to achieve highly tunable, on-chip photonic devices. The other task is to utilize optical forces for light assisted, template self-assembly of nanoparticles. Optical forces are numerically investigated in different configurations. Attractive forces exist between a suspended one-dimensional periodic photonic crystal waveguide and underlying substrate in a silicon-on-insulator platform. It is shown that the optical force can be enhanced by designing the waveguide cross section to make the mode approach the band edge or substrate light line. For periodic waveguides, the optical force is non-monotonic with waveguide-substrate separation. This effect may enable the design of compact, integrated optical power limiters. An analytical method is proposed to calculate optical forces between silicon waveguides based on the perturbation of effective index at fixed frequency. The method is used to investigate the mechanical Kerr effect in a coupled-waveguide system with bipolar forces. It is shown that positive mechanical Kerr coefficient results from either an attractive or repulsive force. An enhanced mechanical Kerr coefficient several orders of magnitude larger than the intrinsic Kerr coefficient is obtained in waveguides for which the optical mode approaches the air light line, given appropriate design of the waveguide dimensions. Optical forces are proposed to tune phase and group birefringence in parallel silicon strip waveguides. Widely tunable phase and group birefringence can be achieved by varying the pump power, with maximum values of 0.026 and 0.13, respectively. The giant phase birefringence allows linear to circular polarization conversion.

Open PDF

Document Details

Document Type
Technical Report
Publication Date
May 01, 2013
Accession Number
ADA611887

Entities

People

  • Jing Ma

Organizations

  • University of Southern California

Tags

Communities of Interest

  • Advanced Electronics

DTIC Thesaurus Topics

  • Crystal Lattices
  • Crystal Structure
  • Crystals
  • Electromagnetic Fields
  • Finite Difference Time Domain
  • Materials Processing
  • Optical Fibers
  • Optical Lattices
  • Optical Phenomena
  • Optical Properties
  • Optics
  • Optomechanics
  • Photonic Crystals
  • Photonic Integrated Circuits
  • Semiconductors
  • Surface Plasmon Polaritons
  • Three Dimensional

Fields of Study

  • Engineering
  • Physics

Readers

  • Microwave Engineering.
  • Nanoscale Plasmonic Nanotechnology
  • Quantum Dot Semiconductor Device Photonics and Graphene Optoelectronic Materials and THz Physics.

Technology Areas

  • Biotechnology
  • Microelectronics