Entanglement-assisted authenticated BB84 protocol

This work delivers a novel user-server authentication procedure exploiting the features of maximally entangled pairs in both an idealistic noiseless scenario and a moderately noisy one. Additionally, we leverage the specific features of our design, which are conveniently suited for inlaying it into the well known BB84 quantum communication protocol. We first define a trivial extension of our initial proposal allowing for such task (symmetric scheme) to then come up with what we denote as asymmetric scheme, better matching practicality. Furthermore, a realistic simulation of the user-server authentication protocol has been achieved by employing a noisy model for both transmission and storage, the latter relying on cavity-enhanced atomic-frequency comb (AFC) memories. While in a noiseless scenario our proposal is ensured to be airtight, considering a certain degree of noise poses a challenge when aiming to actually implement it. We have implemented a deep neural network to distinguish legitimate users from forgery attempts, outperforming a mere statistical approach designed for the same task. Such method achieved a success rate of 0.75 with storage times of \(1\) \(\mu s\) and a user-server distance of \(10\) km.