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Fast and energy-efficient non-volatile III-V-on-silicon photonic phase shifter based on memristors

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arxiv 2305.14271 v1 pith:6AWWG724 submitted 2023-05-23 physics.optics physics.app-ph

Fast and energy-efficient non-volatile III-V-on-silicon photonic phase shifter based on memristors

classification physics.optics physics.app-ph
keywords phasenon-volatileshifterdataenergyphotonicprogrammablesilicon
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Silicon photonics has evolved from lab research to commercial products in the past decade as it plays an increasingly crucial role in data communication for next-generation data centers and high performance computing1. Recently, programmable silicon photonics has also found new applications in quantum2 and classical 3 information processing. A key component of programmable silicon photonic integrated circuits (PICs) is the phase shifter, traditionally realized via the thermo-optic or plasma dispersion effect which are weak, volatile, and power hungry. A non-volatile phase shifter can circumvent these limitations by requiring zero power to maintain the switched phases. Previously non-volatile phase modulation was achieved via phase-change4 or ferroelectric materials5, but the switching energy remains high (pico to nano joules) and the speed is slow (micro to milli seconds). Here, we report a non-volatile III-V-on-silicon photonic phase shifter based on HfO2 memristor with sub-pJ switching energy (~400fJ), representing over an order of magnitude improvement in energy efficiency compared to the state of the art. The non-volatile phase shifter can be switched reversibly using a single 100ns pulse and exhibits an excellent endurance over 800 cycles. This technology can enable future energy-efficient programmable PICs for data centers, optical neural networks, and quantum information processing.

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