Frequency subspace encoding for multiplexed quantum secret sharing

TL;DR

This paper introduces a frequency subspace encoding method for quantum secret sharing that enables multiple independent sessions over a single broadband source, enhancing scalability and resource efficiency in quantum networks.

Contribution

The authors propose a novel frequency correlation-based encoding scheme for quantum secret sharing, reducing the need for multiple sources and enabling scalable multi-user quantum networks.

Findings

Achieved state fidelities of at least 90% for 200 GHz channels.

Demonstrated potential to extend to over 40 frequency bins with dense-wavelength division multiplexing.

Provided a resource-efficient approach for multi-user quantum secret sharing.

Abstract

Quantum secret sharing (QSS) is a multi-party quantum communication protocol that can be realized with bipartite entanglement and relative phase encoding. Previous implementations typically encoded the phase in the pump, applying it across the entire source bandwidth, thereby limiting scalability via wavelength multiplexing. In contrast, we present a variant of the standard QSS protocol that leverages frequency correlations to connect multiple users with a single source. The secret owner, who has access to the source, encodes classical information by applying frequency-dependent phase modulation to a broadband polarization-entangled photon pair. Each frequency channel therefore provides an independent QSS session among the secret owner and a pair of users. We demonstrate state fidelities of at least 90% for a channel pair of the 200 GHz ITU grid, which could be extended to more than 40 frequency bins with adequate dense-wavelength division multiplexed filters. Our results provide a resource-efficient path toward multi-user secret sharing over wavelength-multiplexed networks, eliminating the need for multiple two-photon or multi-photon sources.