Quantum Measurement Without Collapse or Many Worlds: The Branched Hilbert Subspace Interpretation

Abstract

We propose the Branched Hilbert Subspace Interpretation (BHSI) as an alternative perspective on quantum measurement. BHSI describes measurement as a unitary branching of the local Hilbert space into decoherent, independent, and unitarily evolving subspaces, while updating observer states (through their equipment) by causally engaging and disengaging operators. Unlike the Copenhagen Interpretation (CI), BHSI avoids wave function collapse while maintaining the Born rule through the branch weights associated with the initial system state. Unlike the Many-Worlds Interpretation (MWI), BHSI sidesteps parallel worlds by entangling branches with the local environment within a single world. We compare BHSI features with those of CI, MWI, and Bohmian Mechanics (BM). We investigate its implications for the double-slit experiment, Bell tests, Wigner and his friend, black hole radiation, and the delayed-choice quantum eraser. We examine quantum teleportation, demonstrating that locally controlled decoherence and recoherence processes (CDRP) can be observed. Specifically, we suggest experiments using modern Stern-Gerlach interferometers (SGI) to visualize the CDRP, measure branch weights that encode the Born rule, and predict the electromagnetic (EM) phase shift resulting from the independent unitary evolution of decoherent branches. BHSI thus provides a minimalist alternative to interpretations based on collapse or many-worlds.