Temporal nonlocality of a qudit resides in the input state, not the channel, and certifies temporal teleportation up to a fundamental limit

Abstract

Correlations between two moments in time can be too strong for any classical explanation -- and, remarkably, this can happen for a single quantum system measured twice, with no second particle involved. We show that when one qudit is sent through a noisy channel, the strength of this "nonlocality in time" -- the temporal nonlocality robustness TNR -- is carried entirely by the starting state: it vanishes precisely when the input is maximally mixed (completely random), TNR(ρA,E)=0ρA=1/d, for the standard noise families. The resource is not any coherence in the channel but the back-action of the input's mixedness, and it survives even complete decoherence. This is at once a power and a trap. As a power, TNR device-independently lower-bounds the fidelity of temporal teleportation -- sending an unknown state forward in time -- reaching 7/9 at d=3, without trusting the measuring devices. As a trap, because the certified quantity is decoupled from the channel's actual coherence transmission, it can certify more than the channel delivers: an injective (reversible) unitary attains the maximal temporal-Bell signal yet teleports below the classical baseline. We resolve this over-certification completely -- a universal cap TNR(d-1)/d with an exact channel-resolved value, honest certification for the depolarizing channel and for any sufficiently mixed probe, and a proof that no choice of probes makes it channel-universal. Underpinning the results is a unified semidefinite-programming hierarchy of the temporal entanglement, steering and nonlocality robustnesses (TER, TSR, TNR), with a strict lower hierarchy and an upper one conditional on no-signaling in time (NSIT). All structure is verified numerically for d=2 through 5.

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