Wang, Xing M.
(2025)
Quantum Measurement Without Collapse or Many Worlds: The Branched Hilbert Subspace Interpretation.
[Preprint]
Abstract
The interpretation of quantum measurements presents a fundamental challenge in quantum mechanics, with concepts such as the Copenhagen Interpretation (CI), Many-Worlds Interpretation (MWI), and Bohmian Mechanics (BM) offering distinct perspectives. We propose the Branched Hilbert Subspace Interpretation (BHSI), which describes measurement as branching the local Hilbert space of a system into decoherent subspaces. We formalize the mathematical framework of BHSI using branching and the engaging and disengaging unitary operators to relationally and causally update the states of observers. Unlike the MWI, BHSI avoids the ontological proliferation of worlds and copies of observers, realizing the Born rule based on branch weights. Unlike the CI, BHSI retains the essential features of the MWI: unitary evolution and no wavefunction collapse. Unlike the BM, BHSI does not depend on a nonlocal structure, which may conflict with relativity. We compare CI, MWI, and BHSI in the double-slit experiment, Bell tests, Wigner and his friend, the black hole information paradox, and the delayed choice quantum eraser. Additionally, we examine the environmental scale of branching in MWI versus BHSI (maximal vs. minimal) and investigate whether recohering branches can be realized. Overall, BHSI offers a minimalist, unitarity-preserving, collapse-free, and probabilistically inherent alternative interpretation of quantum measurements.
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