A quantum key distribution testbed using a plug&play telecom-wavelength single-photon source

Deterministic solid state quantum light sources are considered key building blocks for future communication networks. While several proof-of-principle experiments of quantum communication using such sources have been realized, most of them required large setups—often involving liquid helium infrastr...

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Bibliographic Details
Published in:Applied physics reviews 2022-03, Vol.9 (1)
Main Authors: Gao, Timm, Rickert, Lucas, Urban, Felix, Große, Jan, Srocka, Nicole, Rodt, Sven, Musiał, Anna, Żołnacz, Kinga, Mergo, Paweł, Dybka, Kamil, Urbańczyk, Wacław, Sȩk, Grzegorz, Burger, Sven, Reitzenstein, Stephan, Heindel, Tobias
Format: Article
Language:English
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Summary:Deterministic solid state quantum light sources are considered key building blocks for future communication networks. While several proof-of-principle experiments of quantum communication using such sources have been realized, most of them required large setups—often involving liquid helium infrastructure or bulky closed-cycle cryotechnology. In this work, we report on the first quantum key distribution (QKD) testbed using a compact benchtop quantum dot single-photon source operating at telecom wavelengths. The plug&play device emits single-photon pulses at O-band wavelengths (1321 nm) and is based on a directly fiber-pigtailed deterministically fabricated quantum dot device integrated into a compact Stirling cryocooler. The Stirling is housed in a 19 in. rack module including all accessories required for stand-alone operation. Implemented in a simple QKD testbed emulating the BB84 protocol with polarization coding, we achieve an multiphoton suppression of g ( 2 ) ( 0 ) = 0.10 ± 0.01 and a raw key rate of up to ( 4.72   ±   0.13 ) kHz using an external pump laser. In this setting, we further evaluate the performance of our source in terms of the quantum bit error ratios, secure key rates, and tolerable losses expected in full implementations of QKD while accounting for finite key size effects. Furthermore, we investigate the optimal settings for a two-dimensional temporal acceptance window applied on the receiver side, resulting in predicted tolerable losses up to 23.19 dB. Not least, we compare our results with previous proof-of-concept QKD experiments using quantum dot single-photon sources. Our study represents an important step forward in the development of fiber-based quantum-secured communication networks exploiting sub-Poissonian quantum light sources.
ISSN:1931-9401
1931-9401
DOI:10.1063/5.0070966