Derivation of Space and Time from Quantum State Transitions

This study proposes a conceptual framework in which time and space are derived from quantum state transitions rather than being treated as fundamental background entities. Temporal progression is interpreted as the ordered sequence of discrete quantum state changes, while spatial structure emerges from relational properties among quantum states.
Within this framework, time is defined operationally as the measurable rate of quantum state evolution, and space arises from correlations and structural relations between quantum systems. The approach suggests that spacetime may be understood as an emergent construct grounded in quantum dynamics rather than as a primary ontological structure.
The implications of this interpretation are discussed in relation to general relativity and quantum mechanics, with attention to cosmological considerations and foundational questions in theoretical physics.