Decoherence theory explains the suppression of interference between branches of a quantum state but does not explain why any particular branch persists as a stable classical history under continued environmental interaction. This unresolved gap lies at the core of the quantum measurement problem. Here we demonstrate that irreversible record formation is a necessary structural condition for the stabilization of quantum histories. Using a minimal open quantum system consisting of a measured qubit coupled to a memory degree of freedom, we show that decoherence alone fails to produce persistent measurement records in the presence of ongoing noise. By contrast, when the memory subsystem is allowed to irreversibly export entropy, stable and distinguishable records emerge robustly. We introduce an operational recordability metric based on the trace-distance distinguishability of conditional memory states and observe a pronounced transition between recordable and non-recordable regimes. These results establish that measurement outcomes do not become classical merely by decohering; they become classical only when they are irreversibly maintained. This mechanism resolves a structural incompleteness in decoherence-based accounts of measurement without invoking wavefunction collapse, observers, or interpretational postulates. Keywords: quantum measurement problem, decoherence, irreversible record formation, open quantum systems, Lindblad dynamics, classical emergence, quantum histories, record stabilization, entropy export, measurement records, trace distance, quantum information, environment-induced decoherence, thermodynamic irreversibility
Brent W. Jonah (Wed,) studied this question.