Decoy state and purification protocols for superior quantum key distribution with imperfect quantum-dot based single photon sources: Theory and Experiment

TL;DR

This paper introduces and experimentally demonstrates two practical QKD protocols using engineered quantum dot sources that outperform traditional weak coherent state protocols, significantly enhancing secure communication distances.

Contribution

Proposes and validates two novel QKD protocols employing engineered quantum dot sources to surpass the performance of state-of-the-art weak coherent state protocols in secure key distribution.

Findings

Protocols exceed WCS performance by more than 3dB in channel loss

Experimental emulation of BB84 with quantum dot sources confirms protocol superiority

Photon statistics engineering enables practical QKD without ideal single photon sources

Abstract

The original proposal of quantum key distribution (QKD) was based on ideal single photon sources, which 40 years later, are still challenging to develop. Therefore, the development of decoy state protocols using weak coherent states (WCS) from lasers, set the frontier in terms of secure key rates and distances. Here, we propose and experimentally demonstrate two simple-to-implement QKD protocols that allow practical, far from ideal sub-Poissonian photon sources to outperform state-of-the-art WCS. By engineering the photon statistics of a biexciton-exciton cascade in room temperature single photon sources based on giant colloidal quantum dots coupled to nanoantennas, we show that either a truncated decoy state protocol or a heralded purification protocol can be employed to achieve a significantly increased performance in terms of the maximal allowed channel loss for secure key creation, which can exceed even that of ideal WCS by more than 3dB. We then experimentally emulate a BB84 QKD using such a quantum dot source, verifying the superiority of our protocols over the best possible BB84 WCS performance. These protocols can be utilized efficiently on a host of various quantum emitters having controllable photon statistics with a finite photon-number basis, offering a practical approach to QKD without the hindering requirements on the single photon purity of the photon source.