Overcoming Intensity Limits for Long-Distance Quantum Key Distribution

Quantum Key Distribution (QKD) enables the sharing of cryptographic keys secured by quantum mechanics. The BB84 protocol assumed single-photon sources, but practical systems rely on weak coherent pulses vulnerable to photon-number-splitting (PNS) attacks. The Gottesman-Lo-L\"utkenhaus-Preskill (GLLP) framework addressed these imperfections, deriving secure key rate bounds under limited PNS. The Decoy-state protocol further improved performance by refining single-photon yield estimates, but still considered multi-photon states as insecure, limiting intensities and thereby constraining key rate and distance. Here, we show that higher intensities can be securely permitted by applying Bayesian inference to estimate key parameters directly from observed data rather than relying on worst-case assumptions. By raising the pulse intensity to 10 photons, we achieve 50 times the key rate and a 62.2% increase in operational range (about 200 km) compared to the decoy-state protocol. Furthermore, we accurately model after-pulsing using a Hidden Markov Model and reveal inaccuracies in decoy-state calculations that may produce erroneous key-rate estimates. By bridging theoretical security and real-world conditions, this Bayesian methodology provides a versatile post-processing step for many discrete-variable QKD protocols, advancing their reach, efficiency, and facilitating broader adoption of quantum-secured communication.