Quantum Key Distribution Using an Integrated Quantum Emitter in Hexagonal Boron Nitride

Quantum Key Distribution (QKD) is considered the most immediate application to be widely implemented amongst a variety of potential quantum technologies. QKD enables sharing secret keys between distant users, using photons as information carriers. The current challenge is to implement these protocols in practice, for real-world conditions, in a robust, and compact manner. Single Photon Sources (SPS) in solid-state materials are prime candidates in this respect. Here, we demonstrate a room temperature, discrete-variable quantum key distribution system using a bright single photon source in hexagonal-boron nitride, operating in free-space. Employing an integrated, “plug and play” photon source system, we have generated keys with one million bits length, and demonstrated a secret key of approximately 70,000 bits, at a quantum bit error rate of 6%, with ε -security of 10 − 10 . Emphasis was put on the inclusion of all known effects impacting the derived security level, thereby demonstrating the most trustworthy QKD system realised with SPSs to date. Our results will be important to achieve meaningful progress with deterministic room-temperature QKD systems.

[1]  C. Schneider,et al.  Atomically-thin single-photon sources for quantum communication , 2022, npj 2D Materials and Applications.

[2]  S. F. Covre da Silva,et al.  Daylight entanglement-based quantum key distribution with a quantum dot source , 2022, Quantum Science and Technology.

[3]  S. Ateş,et al.  Free‐Space Quantum Key Distribution with Single Photons from Defects in Hexagonal Boron Nitride , 2022, Advanced Quantum Technologies.

[4]  R. Malaney,et al.  Integrated room temperature single-photon source for quantum key distribution. , 2022, Optics letters.

[5]  T. Heindel,et al.  Quantum Communication Using Semiconductor Quantum Dots , 2021, Advanced Quantum Technologies.

[6]  S. Burger,et al.  A quantum key distribution testbed using a plug&play telecom-wavelength single-photon source , 2021, Applied Physics Reviews.

[7]  S. Maier,et al.  Bright single photon emitters with enhanced quantum efficiency in a two-dimensional semiconductor coupled with dielectric nano-antennas , 2021, Nature Communications.

[8]  Dong Jiang,et al.  100 Mbps Reconciliation for Quantum Key Distribution Using a Single Graphics Processing Unit , 2021, SN Computer Science.

[9]  Fabio Sciarrino,et al.  Quantum key distribution with entangled photons generated on demand by a quantum dot , 2020, Science Advances.

[10]  Dan Dalacu,et al.  Enhancing secure key rates of satellite QKD using a quantum dot single-photon source , 2020, 2009.11818.

[11]  Yongmei Huang,et al.  Entanglement-based secure quantum cryptography over 1,120 kilometres , 2020, Nature.

[12]  Jian-Wei Pan,et al.  Secure quantum key distribution with realistic devices , 2020 .

[13]  J. Tetienne,et al.  Quantum Emitters in Hexagonal Boron Nitride , 2020, 2020 Conference on Lasers and Electro-Optics (CLEO).

[14]  P. Grünwald,et al.  Estimating the single-photon projection of low-intensity light sources , 2020, Physical Review A.

[15]  S. Reitzenstein,et al.  Tools for the performance optimization of single-photon quantum key distribution , 2019, npj Quantum Information.

[16]  Luke C. G. Govia,et al.  Numerical finite-key analysis of quantum key distribution , 2019, npj Quantum Information.

[17]  P. Grünwald,et al.  Effective second-order correlation function and single-photon detection , 2017, New Journal of Physics.

[18]  D. Englund,et al.  Solid-state single-photon emitters , 2016, Nature Photonics.

[19]  Bing Qi,et al.  Practical challenges in quantum key distribution , 2016, npj Quantum Information.

[20]  Amir K. Khandani,et al.  Experimental quantum key distribution with simulated ground-to-satellite photon losses and processing limitations , 2015, 1512.05789.

[21]  Yasuhiko Arakawa,et al.  Quantum key distribution over 120 km using ultrahigh purity single-photon source and superconducting single-photon detectors , 2015, Scientific Reports.

[22]  Gilles Brassard,et al.  Quantum cryptography: Public key distribution and coin tossing , 2014, Theor. Comput. Sci..

[23]  Kristian Lauritsen,et al.  Evaluation of nitrogen- and silicon-vacancy defect centres as single photon sources in quantum key distribution , 2013, 1310.1220.

[24]  H. Weinfurter,et al.  Free space quantum key distribution over 500 meters using electrically driven quantum dot single-photon sources—a proof of principle experiment , 2013, 2013 Conference on Lasers & Electro-Optics Europe & International Quantum Electronics Conference CLEO EUROPE/IQEC.

[25]  Christian Schneider,et al.  Quantum key distribution using quantum dot single-photon emitting diodes in the red and near infrared spectral range , 2012 .

[26]  Xue-Wen Chen,et al.  99% efficiency in collecting photons from a single emitter. , 2011, Optics letters.

[27]  Jesus Martinez Mateo,et al.  Information Reconciliation for Quantum Key Distribution , 2010 .

[28]  Sellami Ali,et al.  DECOY STATE QUANTUM KEY DISTRIBUTION , 2010 .

[29]  M.A. Bashar,et al.  A Review and Prospects of Quantum Teleportation , 2009, 2009 International Conference on Computer and Automation Engineering.

[30]  David Elkouss,et al.  Efficient reconciliation protocol for discrete-variable quantum key distribution , 2009, 2009 IEEE International Symposium on Information Theory.

[31]  V. Scarani,et al.  The security of practical quantum key distribution , 2008, 0802.4155.

[32]  Valerio Scarani,et al.  Finite-key analysis for practical implementations of quantum key distribution , 2008, 0811.2628.

[33]  H. Lo,et al.  Quantum key distribution with triggering parametric down-conversion sources , 2008, 0803.2543.

[34]  Renato Renner,et al.  Quantum cryptography with finite resources: unconditional security bound for discrete-variable protocols with one-way postprocessing. , 2007, Physical review letters.

[35]  Simon Litsyn,et al.  Efficient Serial Message-Passing Schedules for LDPC Decoding , 2007, IEEE Transactions on Information Theory.

[36]  Evangelos Eleftheriou,et al.  Regular and irregular progressive edge-growth tanner graphs , 2005, IEEE Transactions on Information Theory.

[37]  Rüdiger L. Urbanke,et al.  Design of capacity-approaching irregular low-density parity-check codes , 2001, IEEE Trans. Inf. Theory.