Title :
A low mode confinement integrated waveguide platform for high resolution displacement sensing
Author :
Pruessner, M.W. ; Doewon Park ; Stievater, T.H. ; Rabinovich, W.S.
Author_Institution :
Opt. Sci. Div., Naval Res. Lab. (NRL), Washington, DC, USA
Abstract :
We demonstrate an integrated waveguide technology and apply it to displacement sensing. The waveguide consists of a 175 nm thick Si3N4 core layer with a 3,000 nm SiO2 bottom cladding and exhibits a large evanescent field. Although the nanophotonic waveguides feature sub-X/4 vertical confinement, they are fabrication tolerant with micron-scale lateral features. The technology enables complex photonic circuits without electron-beam lithography, which is commonly required for silicon nanophotonics. An unbalanced Mach-Zehnder interferometer is demonstrated in which the presence of an optical fiber near the waveguide surface induces a phase shift, which correlates with the fiber´s position. We discuss future work and prospects for high-resolution displacement sensing.
Keywords :
Mach-Zehnder interferometers; displacement measurement; fibre optic sensors; integrated optics; nanophotonics; optical waveguides; silicon compounds; Mach-Zehnder interferometer; Si3N4; SiO2; high resolution displacement sensing; integrated waveguide technology; large evanescent field; low mode confinement integrated waveguide; nanophotonic waveguide; optical fiber; photonic circuits; size 175 nm; size 3000 nm; vertical confinement waveguide; Optical device fabrication; Optical fiber sensors; Optical fibers; Optical surface waves;
Conference_Titel :
SENSORS, 2013 IEEE
Conference_Location :
Baltimore, MD
DOI :
10.1109/ICSENS.2013.6688169
