Title :
Tapered Photonic Crystal Microcavities Embedded in Photonic Wire Waveguides With Large Resonance Quality-Factor and High Transmission
Author :
Zain, Ahmad Rifqi Md ; Gnan, Marco ; Chong, Harold M H ; Sorel, Marc ; De La Rue, Richard M.
Author_Institution :
Glasgow Univ., Glasgow
Abstract :
We present the design, fabrication, and characterization of a microcavity that exhibits simultaneously high transmission and large resonance quality-factor (Q-factor). This microcavity is formed by a single-row photonic crystal (PhC) embedded in a 500-nm-wide photonic wire waveguide - and is based on silicon-on-insulator. A normalized transmission of 85%, together with a Q-factor of 18 500, have been achieved experimentally through the use of carefully designed tapering on both sides of each of the hole-type PhC mirrors that form the microcavity. We have also demonstrated reasonably accurate control of the cavity resonance frequency. Simulation of the device using a three-dimensional finite-difference time-domain approach shows good agreement with the experimental results.
Keywords :
finite difference time-domain analysis; microcavities; optical waveguides; photonic crystals; silicon-on-insulator; high transmission; photonic wire waveguides; quality factor; silicon-on-insulator technology; size 500 nm; tapered photonic crystal microcavities; three-dimensional finite-difference time-domain approach; Fabrication; Finite difference methods; Microcavities; Mirrors; Photonic crystals; Q factor; Resonance; Resonant frequency; Silicon on insulator technology; Wire; Microcavities; photonic crystal (PhC); photonic wires (PhWs); quality-factor ( $Q$-factor); silicon-on-insulator (SOI);
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2007.910621
