Title :
Chip-level waveguide-mirror-pillar optical interconnect structure
Author :
Ogunsola, O.O. ; Thacker, H.D. ; Bachim, B.L. ; Bakir, M.S. ; Pikarsky, J. ; Gaylord, T.K. ; Meindl, J.D.
Author_Institution :
Microelectron. Res. Center, Georgia Inst. of Technol., Atlanta, GA
Abstract :
Waveguides, mirrors, and polymer pillars can be integrated together to provide optical interconnects to the chip level. Total internal reflection in the polymer pillar provides a high level of spatial confinement of the light. The metallized mirror terminating the waveguide may be at 45deg or at a nearby angle such as 54.74deg (anisotropically etched silicon) and produce nearly equal coupling efficiencies. For a polymer waveguide, a gold mirror, and a polymer pillar of the dimensions fabricated, the simulated coupling efficiencies are 80.7% or 0.93 dB (45deg mirror) and 82.5% or 0.84 dB (54.74deg mirror), respectively. These simulations together with the fabrication and testing of a 54.74deg mirror configuration demonstrates the viability of the waveguide-mirror-pillar structure, its insensitivity to mirror angle, and its compatibility with current substrate fabrication technologies
Keywords :
gold; integrated optics; mirrors; optical couplers; optical fabrication; optical interconnections; optical polymers; optical testing; optical waveguides; chip level; gold mirror; optical fabrication; optical interconnect; optical testing; polymer pillar; polymer waveguide; total internal reflection; Anisotropic magnetoresistance; Etching; Metallization; Mirrors; Optical device fabrication; Optical interconnections; Optical polymers; Optical reflection; Optical waveguides; Silicon; Finite-difference time-domain (FDTD); mirrors; optical interconnects; optical waveguides; polymer pillars;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2006.879533
