Title :
A Proposal for Loss Engineering in Slow-Light Photonic Crystal Waveguides
Author :
Ebnali-Heidari, Aliakbar ; Prokop, Christoph ; Ebnali-Heidari, Majid ; Karnutsch, Christian
Author_Institution :
Farhangian Univ., Tehran, Iran
Abstract :
The authors present a loss engineering method for slow-light photonic crystal (PhC) waveguides. Our proposed method for engineering the loss is based on optofluidic techniques to produce low propagation loss in the low dispersions slow-light regime. We numerically demonstrate that this approach allows one to control the propagation loss (from 180 to 120 dB/cm) by selective infiltration of suitable fluids into air holes of a PhC waveguide around the group velocity of c/55 to c/70. It is proposed that fabrication imperfections, i.e., roughness and other deviations from an ideal structure that lead to propagation losses, can be compensated by a selective nanoinfiltration method. A loss of 150 dB/cm for loss-engineered waveguides, compared to 230 dB/cm for conventional waveguides, is numerically demonstrated, while both waveguide structures maintain the same group index-bandwidth product.
Keywords :
fluidic devices; nanophotonics; numerical analysis; optical control; optical dispersion; optical fabrication; optical losses; optical waveguides; photonic crystals; refractive index; slow light; air holes; group index-bandwidth product; group velocity; loss-engineered waveguides; low-dispersions slow-light regime; numerical analysis; optical fabrication imperfections; optofluidic techniques; propagation loss control; roughness; selective nanoinfiltration method; slow-light photonic crystal waveguides; Backscatter; Fluids; Indexes; Optical losses; Optical waveguides; Photonic crystals; Propagation losses; Optofluidic; Photonic crystal waveguide; Propagation loss; photonic crystal waveguide; propagation loss; slow-light;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2015.2391196
