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 Vpp, 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.
ABSTRACT
Optical properties of poly-silicon material are investigated to be integrated in new silicon photonics devices, such as capacitive modulators. Test structure fabrication is done on 300 mm wafer using LPCVD deposition: 300 nm thick amorphous silicon layers are deposited on thermal oxide, followed by solid phase crystallization anneal. Rib waveguides are fabricated and optical propagation losses measured at 1.31 µm. Physical analysis (TEM ASTAR, AFM and SIMS) are used to assess the origin of losses. Optimal deposition and annealing conditions have been defined, resulting in 400 nm-wide rib waveguides with only 9.2-10 dB/cm losses.
