Title :
Single-Crystal Silicon Photonic-Crystal Fiber-Tip Pressure Sensors
Author :
Xuan Wu ; Jan, Catherine ; Solgaard, Olav
Author_Institution :
Dept. of Electr. Eng., Stanford Univ., Stanford, CA, USA
Abstract :
The combination of high-mechanical flexibility and high-optical reflectivity makes planar photonic crystal diaphragms excellent mirrors for optical resonators used in fiber-optic pressure sensing. We have developed a standard silicon process to construct a monolithic photonic crystal-based crystalline silicon membrane. We report on three photonic crystal pressure sensors with different compliances, and discuss the following figures of merit: spectral shift sensitivity; optical sensitivity; pressure sensitivity; resolution; and dynamic range. When compared with a sensor made with an oxide diaphragm, each of our sensors is at least an order of magnitude more sensitive, with a spectral shift sensitivity magnitude of up to 8.6 nm/kPa. We show that the fabrication can be tailored to optimize figures of merit depending on the needs of the application.
Keywords :
elemental semiconductors; fibre optic sensors; holey fibres; membranes; mirrors; optical resonators; photonic crystals; pressure measurement; pressure sensors; silicon; Si; fiber-optic pressure sensing; figures of merit; mirror; monolithic photonic crystal-based crystalline silicon membrane; optical resonator; optical sensitivity; oxide diaphragm; planar photonic crystal diaphragm; pressure sensitivity; single-crystal silicon photonic-crystal fiber-tip pressure sensor; spectral shift sensitivity; Cavity resonators; Mirrors; Optical sensors; Sensitivity; Sensor phenomena and characterization; Silicon; Fabry-Pérot; Fabry-P??rot; Pressure sensor; fiber optic sensing; photonic crystal diaphragm; photonic crystal diaphragm.;
Journal_Title :
Microelectromechanical Systems, Journal of
DOI :
10.1109/JMEMS.2014.2360859
