Secure Hybrid Key Growing via Coherence Witnessing and Bipartite Encoding

TL;DR

This paper introduces a practical hybrid quantum-classical key growing protocol that doubles the bit rate, mitigates noise, and maintains security under realistic conditions, enhancing quantum key distribution efficiency.

Contribution

The paper presents a novel hybrid quantum key growing scheme utilizing multiple degrees of freedom, integrating entity authentication, and demonstrating improved performance in noisy, real-world environments.

Findings

Doubling of bit-per-pulse rate compared to conventional schemes

Reduced Quantum Bit Error Rate (QBER) in low-loss regimes

Effective noise mitigation and eavesdropping detection capabilities

Abstract

We propose a novel Hybrid Key Growing (HKG) protocol based on quantum principles and a classical physical-layer assumption. We simultaneously exploit the quantum photon-number and photon-time-bin Degrees of Freedom (DoFs), effectively doubling the bit-per-pulse rate compared to conventional Quantum Key Growing (QKG) schemes. Our protocol integrates entity authentication, and is designed for practical implementation by avoiding reliance on single-photon sources or detectors. By incorporating prior knowledge about the quantum channel, the scheme actively mitigates noise effects, making it suitable for real-world conditions. Under certain assumptions on experimental efficiencies, our approach also promises an increased key generation rate in bits per second. Our simulation results display, first, expected outcomes to gain assurance about the correctness of our implementation and, second, relevant dependencies that showcase desirable properties of our scheme in regimes of low photon loss and dephasing. In particular, within such regimes, our encoding scheme reduces the Quantum Bit Error Rate (QBER) while preserving the ability to detect eavesdropping and identity-forgery attempts.