Quantifying backflash radiation to prevent zero-error attacks in quantum key distribution

Single-photon avalanche diodes (SPADs) are the most widespread commercial solution for single-photon counting in quantum key distribution applications. However, the secondary photon emission that arises from the avalanche of charge carriers that occurs during the detection of a photon may be exploited by an eavesdropper to gain information without inducing errors in the transmission key. In this paper, we characterize such backflash light in gated InGaAs/InP SPADs and discuss its spectral and temporal characterization for different detector models and different operating parameters. We qualitatively bound the maximum information leakage due to backflash light and propose solutions for preventing such leakage. Quantum cryptography: keeping secrets safe from backflash Secondary photons released from photon detector when quantum cryptographic keys are shared between parties represent a significant eavesdropping threat. Attempts to listen in on quantum key distributions are, in theory, detected as automatic changes to quantum states. But Alice Meda from the INRIM in Italy and colleagues have now demonstrated that the detectors used to spot single photons in many commercial quantum key distribution boxes can leak information through ‘backflash’–bursts of light triggered when a photon hits an avalanche photodiode. The team constructed a sensitive new machine for detecting backflashes and determined data leakage rates nearing 10%. As well, each photodetector emitted specific signatures that might give attackers another entry point. Wide-bandwidth filters or special circulators incorporated into the quantum boxes can help secure this breach, the researchers propose.