All-optical switching at multi-100-Gb/s data rates with Mach-Zehnder interferometer switches

Author

Schreieck, Roland P. ; Kwakernaak, Martin H. ; Jackel, Heinz ; Melchior, Hans

Author_Institution

Electron. Lab., Swiss Fed. Inst. of Technol., Zurich, Switzerland

Volume

38

Issue

8

fYear

2002

fDate

8/1/2002 12:00:00 AM

Firstpage

1053

Lastpage

1061

Abstract

We present experimental and theoretical results on ultrafast nonlinear dynamics in InGaAsP semiconductor optical amplifiers (SOAs). Carrier heating, spectral hole burning, and two-photon absorption are analyzed by heterodyne pump-probe experiments which deliver basic model parameters like gain-phase coupling parameters of the material. The impact on the device performance induced by these physical effects is verified by cross-gain/cross-phase experiments on InGaAsP-based SOAs and Mach-Zehnder interferometer switches. In the co-propagation arrangement, the switching window with maximum transmission is shown to be 1.5 ps which translates into demultiplexing capabilities beyond 600 Gb/s. Calculations based on a distributed rate equation model show that, for high-speed applications, the switching window can be limited by pulse saturation and by subpicosecond nonlinear effects.

Keywords

III-V semiconductors; Mach-Zehnder interferometers; gallium arsenide; hot carriers; indium compounds; nonlinear optics; optical hole burning; optical saturation; optical switches; semiconductor optical amplifiers; two-photon processes; 1.5 ps; 100 Gbit/s; 600 Gbit/s; InGaAsP; InGaAsP semiconductor optical amplifiers; InGaAsP-based SOA; Mach-Zehnder interferometer switches; SOA; all-optical switching; carrier heating; co-propagation arrangement; cross-gain/cross-phase experiments; demultiplexing capabilities; distributed rate equation model; gain-phase coupling parameters; heterodyne pump-probe experiments; high-speed applications; maximum transmission; model parameters; multi-100-Gb/s data rates; physical effects; pulse saturation; spectral hole burning; subpicosecond nonlinear effects; switching window; two-photon absorption; ultrafast nonlinear dynamics; Fiber nonlinear optics; High speed optical techniques; Optical interferometry; Optical mixing; Optical pumping; Optical saturation; Optical signal processing; Optical wavelength conversion; Switches; Ultrafast optics;

fLanguage

English

Journal_Title

Quantum Electronics, IEEE Journal of

Publisher

ieee

ISSN

0018-9197

Type

jour

DOI

10.1109/JQE.2002.800994

Filename

1021023