Hybrid quantum photonic integrated circuits

Conference paper (2018)

Authors

A.W.A. Elshaari AlbaNova University Center

I.Z. Esmaeil Zadeh Kavli institute of nanoscience Delft, ImPhys/Optics -

A.W. Fognini Kavli institute of nanoscience Delft, QN/Mol. Electronics & Devices

D. Dalacu National Research Council Canada

Philip J. Poole National Research Council Canada

M. E. Reimer

V.G. Zwiller Kavli institute of nanoscience Delft, AlbaNova University Center, QN/Zwiller Lab

K.D. Jöns QN/Quantum Nanoscience , AlbaNova University Center

Research Group

ImPhys/Optics () (TU Delft)

Quantum dots Quantum photonic circuits Semiconductor nanowires SIN waveguides Singlephoton source

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http://resolver.tudelft.nl/uuid:88bce53b-94a8-4025-8c4b-0743b8eef0c1

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Published Date

13-08-2018

Language

English

Reuse Rights

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Faculty

Applied Sciences

Department

ImPhys/Imaging Physics

Research Group

ImPhys/Optics

Abstract

Quantum photonic integrated circuits require a scalable approach to integrate bright on-demand sources of entangled photon-pairs in complex on-chip quantum photonic circuits. Currently, the most promising sources are based on III/V semiconductor quantum dots. However, complex photonic circuitry is mainly achieved in silicon photonics due to the tremendous technological challenges in circuit fabrication. We take the best of both worlds by developing a new hybrid on-chip nanofabrication approach, allowing to integrate III/V semiconductor nanowire quantum emitters into silicon-based photonics.

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