Integrated rare-Earth doped mode-locked lasers on a CMOS platform

Author(s)

Kärtner, Franz X.; Callahan, Patrick T.; Shtyrkova, Katia; Li, Nanxi; Singh, Neetesh Kumar; Xin, Ming; Ravi, Koustuban; Notaros, Jelena; Magden, Emir Salih; Vermeulen, Diedrik Rene Georgette; Ippen, Erich Peter; Watts, Michael; ... Show more Show less

Abstract

Mode-locked lasers provide extremely low jitter optical pulse trains for a number of applications ranging from sampling of RF-signals and optical frequency combs to microwave and optical signal synthesis. Integrated versions have the advantage of high reliability, low cost and compact. Here, we describe a fully integrated mode-locked laser architecture on a CMOS platform that utilizes rare-earth doped gain media, double-chirped waveguide gratings for dispersion compensation and nonlinear Michelson Interferometers for generating an artificial saturable absorber to implement additive pulse mode locking on chip. First results of devices at 1.9 μm using thulium doped aluminum-oxide glass and operating in the Q-switched mode locking regime are presented.

Date issued

2018-05

URI

https://hdl.handle.net/1721.1/129712

Department

Massachusetts Institute of Technology. Research Laboratory of Electronics
Lincoln Laboratory

Journal

Silicon Photonics: From Fundamental Research to Manufacturing

Publisher

Society of Photo-Optical Instrumentation Engineers (SPIE)

Citation

Kärtner, Franz X. et al. "Integrated rare-Earth doped mode-locked lasers on a CMOS platform." Silicon Photonics: From Fundamental Research to Manufacturing, April 2018, Strasbourg, France, Society of Photo-Optical Instrumentation Engineers, May 2018. © 2018 SPIE

Version: Final published version

ISBN

9781510618985

9781510618992