Spacetime-Probability-Initial Conditions Quantum Mechanics

The full six-dimensional quantum framework, where quantum phenomena are understood as unfolding across space, time, probability, and the full spectrum of initial conditions. In this framework, the quantum state of a system includes not just its spacetime coordinates and probability branches but its complete history—the initial conditions that shaped its evolution. This theory explains why quantum systems retain information about their past, why measurements can reveal not just current state but historical trajectory, and why the universe at its most fundamental level is a record of everything that ever happened. Spacetime-probability-initial conditions quantum mechanics is the physics of memory at the quantum level, where the past is not lost but encoded in the present.

The integration of quantum mechanics with the multiverse, treating quantum phenomena as interactions across different universes within the multiverse. In this framework—closely related to the many-worlds interpretation—superposition is not a single particle in multiple states but multiple universes diverging, each with the particle in one state. Entanglement is not spooky action at a distance but connections across universes. Measurement is not collapse but branching—the universe splitting into copies, each with a different outcome. Multiverse quantum mechanics explains why quantum phenomena seem probabilistic: we only experience one branch, but all branches exist. The theory is elegant, deterministic, and ontologically extravagant—it solves the measurement problem by multiplying universes.