Jorn van Engelen scite author profile

Photonic integration in a micrometer-thick indium phosphide (InP) membrane on silicon (IMOS) offers intrinsic and high-performance optoelectronic functions together with high-index-contrast nanophotonic circuitries. Recently demonstrated devices have shown competitive performances, including high sidemode-suppression ratio (SMSR) lasers, ultrafast photodiodes, and significant improvement in critical dimensions. Applications of the IMOS devices and circuits in optical wireless, quantum photonics, and optical cross-connects have proven their performances and high potential.

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InP membrane integrated photonics research

Jiao

Nishiyama

Tol

et al. 2020

Semicond. Sci. Technol.

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Recently a novel photonic integration technology, based on a thin InP-based membrane, is emerging. This technology offers monolithic integration of active and passive functions in a sub-micron thick membrane. The enhanced optical confinement in the membrane results in ultracompact active and passive devices. The membrane also enables approaches to converge with electronics. It has shown high potential in breaking the speed, energy and density bottlenecks in conventional photonic integration technologies. This paper explains the concept of the InP membrane, discusses the versatility of various technology approaches and reviews the recent advancement in this field.

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Low Loss InP Membrane Photonic Integrated Circuits Enabled by 193-nm Deep UV Lithography

Engelen

Reniers

Bolk

et al. 2019

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InP membrane lasers and active-passive integration

Jiao

Pogoretskii

Engelen

et al. 2019

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Reflecting AWG by Using Photonic Crystal Reflector on Indium-Phosphide Membrane on Silicon Platform

Zhang

Engelen

Reniers

et al. 2019

IEEE Photon. Technol. Lett.

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Jorn van Engelen

Indium Phosphide Membrane Nanophotonic Integrated Circuits on Silicon

InP membrane integrated photonics research

Low Loss InP Membrane Photonic Integrated Circuits Enabled by 193-nm Deep UV Lithography

InP membrane lasers and active-passive integration

Reflecting AWG by Using Photonic Crystal Reflector on Indium-Phosphide Membrane on Silicon Platform

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