Coherence-gated quantum devices via real-time weak measurement

Abstract

Single-photon routers in cavity and circuit QED direct photons by the qubit's energy eigenstate -- a projective decision that destroys coherence. We propose a different primitive: coherence-gated routing, where the decision depends on the magnitude of the qubit's quantum coherence, estimated in real time from simultaneous weak measurements of σx and σz. A photon is accepted if the coherence score S(T) = σxc2 + σyc2, extracted from the conditional density matrix via the stochastic master equation, exceeds a tunable threshold Sth. Certifying coherence at emission enables two applications conventional heralded sources cannot: (i) a quantum random number generator with min-entropy bounded by Bloch-sphere geometry, H∞ ≥ -2\!(1+1-Sth22), and (ii) a phase-tracked photon source whose two-node coherence certification bounds the matter-matter entanglement fidelity after Bell-state measurement. The estimator is itself a security primitive. Benchmarking seven configurations, we find that underestimating detector efficiency (ηa < ηtrue) both stabilizes the numerics and suppresses overcertification. We trace this via a purity-monotonicity result, identify a geometric loophole amplifying purity undercertification into coherence overcertification by an order of magnitude (40×), and prove two complementary tail bounds: an Ornstein-Uhlenbeck comparison giving 4.5\% raw overcertification (empirical 3.7\% from 106 trajectories) and an exponential supermartingale establishing structural exponential decay.