Fabrication of ultrathin and highly flexible InP-based membranes for microoptoelectromechanical systems at 1.55 μm

Author

Strassner, M. ; Esnault, J.C. ; Leroy, L. ; Leclercq, J.-L. ; Garrigues, M. ; Sagnes, I.

Author_Institution

Lab. de Photoniques et de Nanostruct., CNRS, Marcoussis, France

Volume

17

Issue

4

fYear

2005

fDate

4/1/2005 12:00:00 AM

Firstpage

804

Lastpage

806

Abstract

Tunable microcavities have been fabricated to evaluate their tunability in dependence on the membrane thickness. The membrane thickness has been decreased from 615 nm down to a record thickness of 123 nm yielding in a maximum mechanical tunability of 15.15 nm/V². Furthermore, a three-period /spl lambda//4 InP/air-gap high reflective mirror (R > 99.8% at 1.55 μm) with a record wide stopband of more than 1100 nm has been fabricated. These results are achieved thanks to specific metal-organic vapor-phase epitaxy growth parameters.

Keywords

Fourier transform spectra; III-V semiconductors; distributed Bragg reflectors; indium compounds; infrared spectra; integrated optics; membranes; micro-optics; microcavities; micromechanical devices; optical fabrication; optical tuning; refractive index; semiconductor epitaxial layers; vapour phase epitaxial growth; 1.55 mum; 123 nm; InP; flexible InP-based membranes; mechanical tunability; metal-organic vapor-phase epitaxy growth parameters; microoptoelectromechanical systems; mirror; stopband; tunable microcavities; ultrathin InP-based membranes; Air gaps; Biomembranes; Epitaxial growth; Fabrication; Indium phosphide; Microcavities; Mirrors; Optical materials; Tunable circuits and devices; Vertical cavity surface emitting lasers; Distributed Bragg reflector (DBR); microactuators; micromachining; microresonators; wavelength-division multiplexing;

fLanguage

English

Journal_Title

Photonics Technology Letters, IEEE

Publisher

ieee

ISSN

1041-1135

Type

jour

DOI

10.1109/LPT.2005.844007

Filename

1411882