Abstract
The rapid increase in total transmission capacity within and between data centers requires the construction of low-cost, high-capacity optical transmitters. Since a tremendous number of transmitters are required, photonic integrated circuits (PICs) using Si photonics technology enabling the integration of various functional devices on a single chip is a promising solution. A limitation of a Si-based PIC is the lack of an efficient light source due to the indirect bandgap of Si; therefore, hybrid integration technology of III-V semiconductor lasers on Si is desirable. The major challenges are that heterogeneous integration of III-V materials on Si induces the formation of dislocation at high process temperature; thus, the epitaxial regrowth process is difficult to apply. This paper reviews the evaluations conducted on our epitaxial growth technique using a directly bonded III-V membrane layer on a Si substrate. This technique enables epitaxial growth without the fundamental difficulties associated with lattice mismatch or anti-phase boundaries. In addition, crystal degradation correlating with the difference in thermal expansion is eliminated by keeping the total III-V layer thickness thinner than ~350 nm. As a result, various III-V photonic-device-fabrication technologies, such as buried regrowth, butt-joint regrowth, and selective area growth, can be applicable on the Si-photonics platform. We demonstrated the growth of indium-gallium-aluminum arsenide (InGaAlAs) multi-quantum wells (MQWs) and fabrication of lasers that exhibit >25 Gbit/s direct modulation with low energy cost. In addition, selective-area growth that enables the full O-band bandgap control of the MQW layer over the 150-nm range was demonstrated. We also fabricated indium-gallium-arsenide phosphide (InGaAsP) based phase modulators integrated with a distributed feedback laser. Therefore, the directly bonded III-V-on-Si substrate platform paves the way to manufacturing hybrid PICs for future data-center networks.
Highlights
Increased data transmission between and within data centers requires high-capacity and low-cost optical links
Photonic integrated circuits (PICs) using Si photonics technology are promising because mature complementary-metal-oxide-semiconductor (CMOS) fabrication technology enables the integration of various optical devices into a compact chip [1,2,3,4,5,6,7,8,9,10]
As transmitters for data-center application, the footprint and power consumption of directly modulated lasers (DMLs) on a Si substrate should be further improved. This is due to a lack of epitaxial regrowth in III-V/Si bonding; an InGaAlAs/indium phosphide (InP) or indium gallium arsenide phosphide (InGaAsP)/InP buriedheterostructure (BH) fabricated by epitaxial regrowth of InP is essential for reliable, lowpower-consumption DMLs because a BH enables high optical- and carrier-confinement into the active region [42,43]
Summary
Increased data transmission between and within data centers requires high-capacity and low-cost optical links. III-V substrate, and the substrate can be used repeatedly With these bonding techniques, III-V/Si hybrid PICs have been demonstrated and the directly bonded III-V lasers exhibit sufficient optical output power as a continuous wave light source for Si-photonics modulators. As transmitters for data-center application, the footprint and power consumption of DMLs on a Si substrate should be further improved This is due to a lack of epitaxial regrowth in III-V/Si bonding; an InGaAlAs/InP or InGaAsP/InP buriedheterostructure (BH) fabricated by epitaxial regrowth of InP is essential for reliable, lowpower-consumption DMLs because a BH enables high optical- and carrier-confinement into the active region [42,43]. Recent efforts to integrate multi-bandgap III-V photonic devices using epitaxial growth on the Si-photonics platform, such as a wide-wavelength-range laser array and InGaAsP-MZM integrated with a DFB laser, are reported
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
