New lower-bound techniques based on controllable correlation and entanglement yield non-trivial bounds for Haar-random two-qubit unitaries and the first known bounds for CNOT, DCNOT, sqrt(SWAP), and XX gates, with a tight result for CNOT.
A Tight Lower Bound for the BB84-states Quantum-Position-Verification Protocol
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abstract
We use the entanglement sampling techniques developed by Dupuis, Fawzi and Wehner to find a lower bound on the entanglement needed by a coalition of cheater attacking the quantum position verification protocol using the four BB84 states in the scenario where the cheaters have no access to a quantum channel but share a (possibly mixed) entangled state $\tilde{\Phi}$. For a protocol using n qubits, a necessary condition for cheating is that the max- relative entropy of entanglement $E_{\max}(\tilde{\Phi})\ge n-O(\log n)$. This improves previously known best lower bound by a factor $\sim4$, and it is essentially tight, since this protocol is vulnerable to a teleportation based attack using $n-O(1)$ ebits of entanglement.
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quant-ph 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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Lower bounds on non-local computation from controllable correlation
New lower-bound techniques based on controllable correlation and entanglement yield non-trivial bounds for Haar-random two-qubit unitaries and the first known bounds for CNOT, DCNOT, sqrt(SWAP), and XX gates, with a tight result for CNOT.