Experimental implementation of secure anonymous protocols on an eight-user quantum network
This work provides enhanced privacy-preserving communication for users of quantum networks by enabling anonymous message transmission, addressing a limitation of standard Quantum Key Distribution.
This paper experimentally implemented five information-theoretically secure anonymity protocols on an eight-user quantum network using polarization-entangled photon pairs. The protocols enable anonymous broadcasting, allowing one user to reveal a bit of information while keeping their identity hidden, and maintain sender anonymity if fewer than six users are dishonest.
Anonymity in networked communication is vital for many privacy-preserving tasks. Secure key distribution alone is insufficient for high-security communications, often knowing who transmits a message to whom and when must also be kept hidden from an adversary. Here we experimentally demonstrate 5 information-theoretically secure anonymity protocols on an 8 user city-wide quantum network using polarisation-entangled photon pairs. At the heart of these protocols is anonymous broadcasting, which is a cryptographic primitive that allows one user to reveal one bit of information while keeping her identity anonymous. For a network of $n$ users, the protocols retain anonymity for the sender, given less than $n-2$ users are dishonest. This is one of the earliest implementations of genuine multi-user cryptographic protocols beyond standard QKD. Our anonymous protocols enhance the functionality of any fully-connected Quantum Key Distribution network without trusted nodes.