GST-on-silicon hybrid nanophotonic integrated circuits: a non-volatile quasi-continuously reprogrammable platform Article Swipe

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Materials science Silicon Silicon photonics Extinction ratio Optoelectronics Nanophotonics Resonator Electronic circuit Photonics Optical switch Photonic integrated circuit Phase modulation Laser Attenuation Modulation (music) Hybrid silicon laser Optics Phase noise Electrical engineering Physics Engineering Acoustics Wavelength

Jiajiu Zheng , Amey Khanolkar , Peipeng Xu , Shane Colburn , Sanchit Deshmukh , Jason D. Myers , Jesse A. Frantz , Eric Pop , Joshua R. Hendrickson , J. K. Doylend , Nicholas Boechler , Arka Majumdar ·

YOU? · · 2018 · Open Access · · DOI: https://doi.org/10.1364/ome.8.001551 · OA: W2804944405

Reconfiguration of silicon photonic integrated circuits relying on the weak, volatile thermo-optic or electro-optic effect of silicon usually suffers from a large footprint and energy consumption. Here, integrating a phase-change material, Ge2Sb2Te5 (GST) with silicon microring resonators, we demonstrate an energy-efficient, compact, non-volatile, reprogrammable platform. By adjusting the energy and number of free-space laser pulses applied to the GST, we characterize the strong broadband attenuation and optical phase modulation effects of the platform, and perform quasi-continuous tuning enabled by thermo-optically-induced phase changes. As a result, a non-volatile optical switch with a high extinction ratio, as large as 33 dB, is demonstrated.

Keywords: Materials science · Silicon · Silicon photonics · Extinction ratio · Optoelectronics · Nanophotonics · Resonator · Electronic circuit · Photonics · Optical switch · Photonic integrated circuit · Phase modulation · Laser · Attenuation · Modulation (music) · Hybrid silicon laser · Optics · Phase noise · Electrical engineering · Physics

GST-on-silicon hybrid nanophotonic integrated circuits: a non-volatile quasi-continuously reprogrammable platform Article Swipe

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