The Quantum State Continuity Problem and Temporal Enforcement Against Fork Attacks

Abstract

We introduce the Quantum State Continuity Problem (QSCP), a security objective orthogonal to identity authentication that captures whether a systems current execution is a legitimate continuation of a unique past execution. We show that classical and stateless quantum authentication mechanisms fail to enforce continuity and remain vulnerable to fork attacks. To address this gap, we propose the Quantum State Continuity Witness (QSCW), a minimal quantum-assisted primitive that enforces temporal linkage of execution through stateful quantum evolution and cumulative auditing. Using a GHZ-based toy instantiation and extensive simulation, we demonstrate that temporal enforcement suppresses fork attacks with exponential decay in success probability, while remaining robust to noise and system parameters. Our results highlight execution continuity as a distinct and underexplored dimension of system security.

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