Title :
Quasi-Phase-Matched Faraday Rotation in Semiconductor Waveguides With a Magnetooptic Cladding for Monolithically Integrated Optical Isolators
Author :
Hutchings, D.C. ; Holmes, B.M. ; Cui Zhang ; Dulal, P. ; Block, A.D. ; Sang-Yeob Sung ; Seaton, Nicholas C. A. ; Stadler, B.J.H.
Author_Institution :
Sch. of Eng., Univ. of Glasgow, Glasgow, UK
Abstract :
Strategies are developed for obtaining nonreciprocal polarization mode conversion, also known as Faraday rotation, in waveguides in a format consistent with silicon-on-insulator or III-V semiconductor photonic integrated circuits. Fabrication techniques are developed using liftoff lithography and sputtering to obtain garnet segments as upper claddings, which have an evanescent wave interaction with the guided light. A mode solver approach is used to determine the modal Stokes parameters for such structures, and design considerations indicate that quasi-phase-matched Faraday rotation for optical isolator applications could be obtained with devices on the millimeter length scale.
Keywords :
Faraday effect; III-V semiconductors; aluminium compounds; gallium arsenide; garnets; integrated optics; optical fabrication; optical phase matching; optical waveguides; sputtering; Al0.27Ga0.73As; GaAs; evanescent wave interaction; liftoff lithography; magnetooptic cladding; modal Stokes parameter; monolithically integrated optical isolator; nonreciprocal polarization mode conversion; optical fabrication techniques; quasiphase matched Faraday rotation; semiconductor photonic integrated circuit; semiconductor waveguide; silicon-on-insulator; sputtering method; Magnetophotonics; integrated photonic systems; waveguide devices;
Journal_Title :
Photonics Journal, IEEE
DOI :
10.1109/JPHOT.2013.2292339
