TY - GEN
T1 - Reduction of Ge-on-Si waveguide propagation loss by laser and hydrogen annealing
AU - Lim, Leh Woon
AU - Fong, Andrew Whye Keong
AU - Ang, Rachel Chen Fang
AU - Voo, Roth Qin Gui
AU - Teh, Justin Nian Hong
AU - Md Husni, Md Hazwani Khairy
AU - Cai, Hong
AU - Tobing, Landobasa Y.M.
AU - Li, Nanxi
AU - Chung, Surasit
AU - Lee, Lennon Yao Ting
N1 - Publisher Copyright:
© 2023 SPIE.
PY - 2023/2
Y1 - 2023/2
N2 - Germanium-on-Silicon (Ge-on-Si) platform has been demonstrated as an excellent candidate for mid-infrared photonics applications, including on-chip mid-infrared spectroscopy and biochemical sensing. However, this platform is often saddled by high propagation loss due to a combination of threading dislocation defects at the Ge/Si interface, absorption in the silicon for λ > 8 μm, and surface scattering due to sidewall roughness. This work investigates the effects on loss reduction through different annealing techniques on Ge-on-Si waveguides fabricated using CMOS-compatible processes. We explore the use of local laser annealing at waveguide sidewalls, whereby the fluence was varied. A non-local annealing technique in hydrogen ambient was also employed as comparison. The propagation losses for wavelengths, ranging from λ = 5 μm to λ = 11 μm, were systematically characterized by fabricating waveguide and grating coupler structures on the same chip. Cutback measurements were performed by varying the waveguide length (of the same width) from L = 1 mm to L = 4 mm. Both hydrogen and laser annealing experiments show marked reduction in the propagation loss, by up to 27% and 46% respectively. This finding paves the way for post-processing techniques to reduce propagation loss in Ge-on-Si platform, which will enable various on-chip mid-IR applications in the future.
AB - Germanium-on-Silicon (Ge-on-Si) platform has been demonstrated as an excellent candidate for mid-infrared photonics applications, including on-chip mid-infrared spectroscopy and biochemical sensing. However, this platform is often saddled by high propagation loss due to a combination of threading dislocation defects at the Ge/Si interface, absorption in the silicon for λ > 8 μm, and surface scattering due to sidewall roughness. This work investigates the effects on loss reduction through different annealing techniques on Ge-on-Si waveguides fabricated using CMOS-compatible processes. We explore the use of local laser annealing at waveguide sidewalls, whereby the fluence was varied. A non-local annealing technique in hydrogen ambient was also employed as comparison. The propagation losses for wavelengths, ranging from λ = 5 μm to λ = 11 μm, were systematically characterized by fabricating waveguide and grating coupler structures on the same chip. Cutback measurements were performed by varying the waveguide length (of the same width) from L = 1 mm to L = 4 mm. Both hydrogen and laser annealing experiments show marked reduction in the propagation loss, by up to 27% and 46% respectively. This finding paves the way for post-processing techniques to reduce propagation loss in Ge-on-Si platform, which will enable various on-chip mid-IR applications in the future.
KW - Germanium-on-Silicon
KW - hydrogen annealing
KW - laser annealing
KW - mid-infrared photonics
UR - http://www.scopus.com/inward/record.url?scp=85159775146&partnerID=8YFLogxK
U2 - 10.1117/12.2649846
DO - 10.1117/12.2649846
M3 - Conference article published in proceeding or book
AN - SCOPUS:85159775146
T3 - Proceedings of SPIE - The International Society for Optical Engineering
BT - Integrated Optics
A2 - Garcia-Blanco, Sonia M.
A2 - Cheben, Pavel
PB - SPIE
T2 - Integrated Optics: Devices, Materials, and Technologies XXVII 2023
Y2 - 30 January 2023 through 2 February 2023
ER -