Cavity-Enhanced IR Absorption in Planar Chalcogenide Glass Microdisk Resonators: Experiment and Analysis

Author(s)

Kimerling, Lionel C.; Hu, Juejun; Carlie, Nathan; Petit, Laeticia; Agarwal, Anuradha Murthy

Abstract

Planar microdisk optical resonators fabricated from Ge[subscript 23]Sb[subscript 7]S[subscript 70] chalcogenide glass on a silicon substrate are applied for cavity-enhanced spectroscopic measurement of chemical molecular absorption fingerprint. A 0.02 cm- 1 detection limit for these devices is demonstrated. This detection limit represents a threefold improvement as compared to a straight waveguide sensor, while the physical device length is reduced by 40-fold. The reduction in device footprint with enhanced sensitivity makes the structure attractive for ldquosensor-on-a-chiprdquo device applications. We also present a design optimization approach for cavity-enhanced IR absorption spectroscopy using traveling-wave resonators, which indicates that further performance improvement can be achieved in optimally coupled, low-loss resonant cavities.

Date issued

2009-10

URI

http://hdl.handle.net/1721.1/59387

Department

Massachusetts Institute of Technology. Materials Processing Center
Massachusetts Institute of Technology. Department of Materials Science and Engineering

Journal

Journal of Lightware Technology

Publisher

Institute of Electrical and Electronics Engineers

Citation

Juejun Hu et al. “Cavity-Enhanced IR Absorption in Planar Chalcogenide Glass Microdisk Resonators: Experiment and Analysis.” Lightwave Technology, Journal of 27.23 (2009): 5240-5245. © Copyright 2009 IEEE

Version: Final published version

Other identifiers

INSPEC Accession Number: 10916411

ISSN

0733-8724

Keywords

sulfur compounds, optical resonators, microresonators, integrated optics, IR spectroscopy, glass, chemical analysis, Amorphous materials