M.N. Sysak scite author profile

We report a waveguide photodetector utilizing a hybrid waveguide structure consisting of AlGaInAs quantum wells bonded to a silicon waveguide. The light in the hybrid waveguide is absorbed by the AlGaInAs quantum wells under reverse bias. The photodetector has a fiber coupled responsivity of 0.31 A/W with an internal quantum efficiency of 90 % over the 1.5 mum wavelength range. This photodetector structure can be integrated with silicon evanescent lasers for power monitors or integrated with silicon evanescent amplifiers for preamplified receivers.

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Hybrid silicon evanescent devices

Fang

et al. 2007

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Hybrid Silicon Photonics for Optical Interconnects

Heck

Chen

Fang

et al. 2011

IEEE J. Select. Topics Quantum Electron.

202

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Abstract-In this paper, we review the hybrid silicon photonic integration platform and its use for optical links. In this platform, a III/V layer is bonded to a fully processed silicon-on-insulator wafer. By changing the bandgap of the III/V quantum wells (QW), lowthreshold-current lasers, high-speed modulators, and photodetectors can be fabricated operating at wavelengths of 1.55 μm. With a QW intermixing technology, these components can be integrated with each other and a complete high-speed optical interconnect can be realized on-chip. The hybrid silicon bonding and process technology are fully compatible with CMOS-processed wafers because high-temperature steps and contamination are avoided. Full wafer bonding is possible, allowing for low-cost and large-volume device fabrication.

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1310nm silicon evanescent laser

Chang¹,

Fang²,

Sysak³

et al. 2007

Opt. Express

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Experimental and theoretical thermal analysis of a Hybrid Silicon Evanescent Laser

Sysak¹,

Park²,

Fang³

et al. 2007

Opt. Express

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In this work we present both experimental and theoretical thermal analysis of an electrically pumped hybrid silicon evanescent laser. Measurements of an 850 µm long Fabry-Perot structure show an overall characteristic temperature of 51 o C, an above threshold characteristic temperature of 100 o C, and a thermal impedance of 41.8 o C/W. Finite element analysis of the laser structure predicts a thermal impedance of 43.5 o C/W, which is within 5% of the experimental results. Using the overall characteristic temperature, above threshold characteristic temperature, and the measured thermal impedance, the continuous wave output power vs. current from the laser is simulated and is in good agreement with experiment.

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M.N. Sysak

A hybrid AlGaInAs-silicon evanescent waveguide photodetector

Hybrid silicon evanescent devices

Hybrid Silicon Photonics for Optical Interconnects

1310nm silicon evanescent laser

Experimental and theoretical thermal analysis of a Hybrid Silicon Evanescent Laser

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