SiGe-enhanced Si capacitive modulator integration in a 300 mm silicon photonics platform for low power consumption

Maurin Douix; Diego Perez-Galacho; Ismael Charlet; Charles Baudot; Pablo Acosta-Alba; Sébastien Kerdilès; Catherine Euvrard; Philippe Grosse; Jonathan Planchot; Romuald Blanc; Rémi Beneyton; Olivier Gourhant; Sébastien Crémer; Aurélie Souhaité; Nathalie Vulliet; Laurent Vivien; Delphine Marris-Morini; Frédéric Boeuf

doi:10.1364/OE.27.017701

SiGe-enhanced Si capacitive modulator integration in a 300 mm silicon photonics platform for low power consumption

Opt Express. 2019 Jun 24;27(13):17701-17707. doi: 10.1364/OE.27.017701.

Authors

Maurin Douix, Diego Perez-Galacho, Ismael Charlet, Charles Baudot, Pablo Acosta-Alba, Sébastien Kerdilès, Catherine Euvrard, Philippe Grosse, Jonathan Planchot, Romuald Blanc, Rémi Beneyton, Olivier Gourhant, Sébastien Crémer, Aurélie Souhaité, Nathalie Vulliet, Laurent Vivien, Delphine Marris-Morini, Frédéric Boeuf

PMID: 31252726
DOI: 10.1364/OE.27.017701

Abstract

The successful integration of capacitive phase shifters featuring a p-type strained SiGe layer in a 300 mm silicon photonics platform is presented. The phase shift is evaluated with a voltage swing of only 0.9 V_pp, compatible with CMOS technology. A good correlation is shown between the phase shift efficiency from 10 to 60°/mm and the capacitive oxide thickness varying from 15 to 4 nm. Corresponding insertion losses are as low as 3 dB/mm thanks to the development of low loss poly-silicon and to a careful design of the doped layers within the waveguide. The thin SiGe layer brings an additional 20% gain in efficiency due to higher hole efficiency in strained SiGe.