Title :
Resonant cavity enhanced Ge photodetectors for 1550 nm operation on reflecting Si substrates
Author :
Dosunmu, Olufemi I. ; Cannon, Douglas D. ; Emsley, Matthew K. ; Ghyselen, Bruno ; Liu, Jifeng ; Kimerling, Lionel C. ; Ünlü, M. Selim
Author_Institution :
Boston Univ., MA, USA
Abstract :
We have fabricated and characterized the first resonant cavity-enhanced germanium photodetectors on double silicon-on-insulator substrates (Ge-DSOI) for operation around the 1550-nm communication wavelength and have demonstrated over four-fold improvement in quantum efficiency compared to its single-pass counterpart. The DSOI substrate is fabricated using an ion-cut process and optimized for high reflectivity (>90%) in the 1300-1600-nm wavelength range, whereas the Ge layer is grown using a novel two-step ultra-high vacuum/chemical vapor deposition direct epitaxial growth technique. We have simulated a Ge-DSOI photodetector optimized for operation at 1550 nm, exhibiting a quantum efficiency of 76% at 1550 nm given a Ge layer thickness of only 860 nm as a result of both strain-induced and resonant cavity enhancement. For this Ge thickness, we estimate a transit time-limited 3-dB bandwidth of approximately 25 GHz.
Keywords :
cavity resonators; chemical vapour deposition; elemental semiconductors; germanium; integrated optoelectronics; photodetectors; reflectivity; semiconductor device testing; semiconductor growth; silicon-on-insulator; vapour phase epitaxial growth; 1300 to 1600 nm; 76 percent; 860 nm; Ge photodetectors; Ge-Si; Si; absorption enhancement; bandgap narrowing; chemical vapor deposition; direct epitaxial growth; double silicon-on-insulator substrates; ion-cut process; reflecting Si substrates; reflectivity; resonant cavity; strain-induced enhancement; ultra-high vacuum deposition; Bandwidth; Chemical vapor deposition; Epitaxial growth; Germanium; Photodetectors; Reflectivity; Resonance; Silicon on insulator technology; Substrates; Vacuum technology; Absorption enhancement; SOI; bandgap narrowing; germanium; ion cut; photodetector; resonant cavity; silicon-on-insulator;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2004.833900
