Indium Phosphide Membrane Nanophotonic Integrated Circuits on Silicon

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 si...

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Veröffentlicht in:	Physica status solidi. A, Applications and materials science Applications and materials science, 2020-02, Vol.217 (3), p.n/a
Hauptverfasser:	Jiao, Yuqing, van der Tol, Jos, Pogoretskii, Vadim, van Engelen, Jorn, Kashi, Amir Abbas, Reniers, Sander, Wang, Yi, Zhao, Xinran, Yao, Weiming, Liu, Tianran, Pagliano, Francesco, Fiore, Andrea, Zhang, Xuebing, Cao, Zizheng, Kumar, Rakesh Ranjan, Tsang, Hon Ki, van Veldhoven, Rene, de Vries, Tjibbe, Geluk, Erik-Jan, Bolk, Jeroen, Ambrosius, Huub, Smit, Meint, Williams, Kevin
Format:	Artikel
Sprache:	eng
Schlagworte:	indium phosphide Integrated circuits Membranes nanophotonics Optoelectronic devices Phosphides Photodiodes photonic integrated circuits photonic integration Photonics semiconductor laser Silicon waveguides
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creator	Jiao, Yuqing van der Tol, Jos Pogoretskii, Vadim van Engelen, Jorn Kashi, Amir Abbas Reniers, Sander Wang, Yi Zhao, Xinran Yao, Weiming Liu, Tianran Pagliano, Francesco Fiore, Andrea Zhang, Xuebing Cao, Zizheng Kumar, Rakesh Ranjan Tsang, Hon Ki van Veldhoven, Rene de Vries, Tjibbe Geluk, Erik-Jan Bolk, Jeroen Ambrosius, Huub Smit, Meint Williams, Kevin
description	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 side‐mode‐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. Indium phosphide (InP) membrane photonics on silicon (IMOS) combines the high‐density nanophotonic circuitries and the high‐efficiency direct‐bandgap optoelectronics in a single micrometer‐thick membrane layer. It enables strong light‐matter interaction in the membrane, leading to a range of performance enhancements. Integrating this InP membrane on electronics wafer will enable revolutionary cointegration and convergence of photonics and electronics.
doi_str_mv	10.1002/pssa.201900606
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subjects	indium phosphide Integrated circuits Membranes nanophotonics Optoelectronic devices Phosphides Photodiodes photonic integrated circuits photonic integration Photonics semiconductor laser Silicon waveguides
title	Indium Phosphide Membrane Nanophotonic Integrated Circuits on Silicon
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