Yong-hwack Shin scite author profile

An O-band DFB laser heterogeneously integrated on bulk-silicon platform is presented. A high wall plug efficiency of over 8% up to 70°C is achieved due to efficient heat dissipation from III/V active region to silicon platform. The single-mode operation is maintained in a wide current range with side-mode suppression ratio over 45dB. This result completes the optical device library suite for the bulk-silicon platform used in most semiconductor products.

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Bulk-Si photonics technology for DRAM interface [Invited]

Byun

Bok

Cho

et al. 2014

Photon. Res.

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Si-based optical I/O for optical memory interface

Shin

Byun

et al. 2012

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Bulk-Si Platform: Born for DRAM, Upgraded With On-Chip Lasers, and Transplanted to LiDAR

Shin

Byun

Shim

et al. 2022

J. Lightwave Technol.

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The CMOS industry has been expecting silicon photonics to provide photonic and electro-photonic integrated circuits based on the CMOS processes and infrastructures for scalability of incumbent technology evolutions and creation of novel technologies. However, the compatibility with the legacy CMOS has been compromised with the development convenience of early silicon photonics in that the specialty silicon-on-insulator substrates have been widely used as integration platforms. Since this specialty substrate may hinder the photonics integration with legacy volume products later, a legacy-friendly integration platform with a generic bulk-silicon substrate has been developed for better compatibility. This paper overviews the bulk-silicon photonics platform born for DRAM integration, upgraded with III/V-on-bulk-Si lasers, and transplanted to LiDAR applications requiring the virtuous cycle of cost and volume. The photonics integration with DRAM was to resolve the speed-capacity tradeoff in the DRAM interconnects, and technical feasibility as well as lessons learned from the integration attempt are reviewed. The bulk-silicon device performance approaches that of silicon-oninsulator devices with the thermal advantage of ~40-% lower thermal impedance and the optical disadvantage of ~0.4-dB/mm higher waveguide loss. In the LiDAR applications, detection performance up to ~20 m at 20 fps by a single-chip scanner integrating tunable laser, semiconductor optical amplifiers, and optical phased array are presented with future outlooks.

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Yong-hwack Shin

Heterogeneously integrated ligtht sources on bulk-silicon platform

O-band DFB laser heterogeneously integrated on a bulk-silicon platform

Bulk-Si photonics technology for DRAM interface [Invited]

Si-based optical I/O for optical memory interface

Bulk-Si Platform: Born for DRAM, Upgraded With On-Chip Lasers, and Transplanted to LiDAR

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