The merger between integrated photonics and quantum optics promises new
opportunities within photonic quantum technology with the very significant
progress on excellent photon-emitter interfaces and advanced optical circuits.
A key missing functionality is rapid circuitry reconfigurability that
ultimately does not introduce loss or emitter decoherence, and operating at a
speed matching the photon generation and quantum memory storage time of the
on-chip quantum emitter. This ambitious goal requires entirely new active
quantum-photonic devices by extending the traditional approaches to
reconfigurability. Here, by merging nano-optomechanics and deterministic
photon-emitter interfaces we demonstrate on-chip single-photon routing with low
loss, small device footprint, and an intrinsic time response approaching the
spin coherence time of solid-state quantum emitters. The device is an essential
building block for constructing advanced quantum photonic architectures
on-chip, towards, e.g., coherent multi-photon sources, deterministic
photon-photon quantum gates, quantum repeater nodes, or scalable quantum
networks.Comment: 7 pages, 3 figures, supplementary informatio

Liu, Zhe

Lodahl, Peter

Ludwig, Arne

Midolo, Leonardo

Papon, Camille

Schott, Rüdiger

Stobbe, Søren

Thyrrestrup, Henri

Wieck, Andreas D.

Zhou, Xiaoyan

English

arXiv

Nielsen, Henri Thyrrestrup

Copenhagen University Research Information System

Nanomechanical single-photon routing

The active routing of photons using rapid reconfigurable integrated circuits is a key functionality for quantum-information processing. Typical waveguide-based optical switches rely on the modulation of the refractive index, producing a modest variation of the phase of the optical fields. Mechanical motion of nanophotonic structures, on the contrary, can be tailored to produce a much larger effect, without introducing loss or emitter decoherence and operating at a speed matching the quantum memory storage time of the on-chip quantum emitter. Here we demonstrate a compact and low-loss nano-opto-electromechanical single-photon router, based on two coupled waveguides whose distance is adjusted on demand by an external voltage. We show controllable two-port routing of single photons emitted from quantum dots embedded in the same chip. We report a maximum splitting ratio &gt;23 dB, insertion loss of 0.67 dB, and sub-microsecond response time. The device is an essential building block for constructing advanced quantum photonic architectures on-chip, towards, e.g., coherent multi-photon sources, deterministic photon- photon quantum gates, quantum-repeater nodes, or scalable quantum networks. (C) 2019 Optical Society of America under the terms of the OSA Open Access Publishing Agreemen

Schott, Ruediger

D Wieck, Andreas

Online Research Database In Technology

https://curis.ku.dk/ws/files/217151758/optica_6_4_524.pdf

Nanomechanical single-photon routing

Abstract

Similar works

Full text

Available Versions

Copenhagen University Research Information System

Online Research Database In Technology