This paper presents the Conscious Collapse Theory (CCT), an interdisciplinary framework proposing that quantum branching is real but temporary, emerging during conscious deliberation and resolving through conscious choice. The theory proposes a solution to the quantum measurement problem and offers a resolution to the identity and accountability challenges commonly associated with the Many-Worlds Interpretation (MWI) through the Uniqueness Principle, according to which the universe returns to a single timeline following each decision event. Formally, CCT is grounded in a hybrid First-Passage Continuous Spontaneous Localization (FP-CSL) mechanism that links the deliberation interval to neural accumulator models and the temporal structure identified in Libet’s readiness potential experiments. The framework further introduces an informational-thermodynamic account of conscious collapse based on Landauer’s Principle, predicting a thermodynamic cost proportional to the von Neumann entropy reduction associated with decision formation. Extending the theory beyond anthropocentric formulations, CCT adopts an Integrated Information Theory () threshold condition to define the class of systems capable of inducing branching and collapse dynamics. The framework generates four quantitatively testable predictions involving neural-quantum correlations, collapse timing, consciousness-dependent decoherence signatures, and quantum-computing-based collapse experiments. By combining concepts from quantum foundations, cognitive neuroscience, information theory, and the philosophy of mind, CCT provides a mathematically structured and empirically falsifiable approach to investigating the relationship between consciousness and quantum state reduction.
Wael ouesleti (Sat,) studied this question.