Quantum key distribution with post-processing driven by physical unclonable functions

TL;DR

This paper explores integrating physical unclonable functions into quantum key distribution systems to reduce the need for pre-shared keys and enable real-time device authentication, enhancing security and scalability.

Contribution

It proposes a method to incorporate physical unclonable functions into quantum key distribution to facilitate pre-shared key generation and device authentication with minimal security compromise.

Findings

Physical unclonable functions can be integrated into QKD systems.

This integration enables real-time device authentication.

Pre-shared key generation can be facilitated with minimal security impact.

Abstract

Quantum key-distribution protocols allow two honest distant parties to establish a common truly random secret key in the presence of powerful adversaries, provided that the two users share beforehand a short secret key. This pre-shared secret key is used mainly for authentication purposes in the post-processing of classical data that have been obtained during the quantum communication stage, and it prevents a man-in-the-middle attack. The necessity of a pre-shared key is usually considered as the main drawback of quantum key-distribution protocols, which becomes even stronger for large networks involving more that two users. Here we discuss the conditions under which physical unclonable function can be integrated in currently available quantum key-distribution systems, in order to facilitate the generation and the distribution of the necessary pre-shared key, with the smallest possible cost in the security of the systems. Moreover, the integration of physical unclonable functions in quantum key-distribution networks allows for real-time authentication of the devices that are connected to the network.