Revision as of 16:43, 22 July 2025 edit 2601:645:8480:c020:55b5:db16:a758:a7d5 (talk) Changed the introduction - there was criticism about "pseudo-science", but at least three independend publishers, including Wiley, Elsevier, and MDPI have peer reviewed and published work on the QMM. Also, the New Scientist - the world's most read popular science magazine - reported on it. See the Talk Page. ← Previous edit		Revision as of 17:04, 22 July 2025 edit undo 2601:645:8480:c020:55b5:db16:a758:a7d5 (talk) Reference correction Next edit →
Line 17: The '''Quantum Memory Matrix''' ('''QMM''') is a proposed framework in quantum gravity and unified-field research that models space-time as a discrete lattice of Planck-scale “memory cells”. Each cell possesses a finite-dimensional Hilbert space and can record, in the form of a reversible ''quantum imprint'', the full quantum state of any field that interacts with it.~~<ref~~ ~~name="Neukart2024Entropy1039"~~Because />the imprints can later be retrieved through unitary operations, QMM aims to preserve unitarity in extreme scenarios such as black-hole evaporation and cosmic bounces, while simultaneously furnishing an ultraviolet cut-off and a natural route to unification of the four fundamental interactions. Because the imprints can later be retrieved through unitary operations, QMM aims to preserve unitarity in extreme scenarios such as black-hole evaporation and cosmic bounces, while simultaneously furnishing an ultraviolet cut-off and a natural route to unification of the four fundamental interactions. [[File:QMM_space_time_cells.png\|thumb\|upright=1.20\|Planck-scale discretization envisioned by QMM.<ref name="Neukart2024" />]] ==Historical background== * '''2024 (~~December~~November).''' Publication of "''The Quantum Memory Matrix": ~~introduces~~A Unified Framework for the Black Hole Information Paradox'' lays out the Planck-scale “memory-cell” hypothesis, ~~and~~introduces local imprint operators, and ~~addresses~~proposes a unitary resolution of the [[Black hole information paradox]].<ref name="Neukart2024">{{cite journal \|last1=Neukart \|first1=Florian \|last2=Brasher \|first2=Reuben \|last3=Marx \|first3=Eike \|title=The Quantum Memory Matrix: A Unified Framework for the Black Hole Information Paradox \|journal=Entropy \|volume=26 \|issue=12 \|pages=1039 \|year=2024 \|doi=10.3390/e26121039 \|url=https://www.mdpi.com/1099-4300/26/12/1039 \|access-date=22 July 2025}}</ref> * '''2024 (December).''' An IBM Quantum experiment demonstrates reversible imprinting and retrieval.<ref name="Arxiv2502">{{cite arXiv \|last1=Neukart \|first1=Florian \|last2=Marx \|first2=Eike \|last3=Vinokur \|first3=Valerii \|eprint=2502.15766 \|title=Reversible Imprinting and Retrieval of Quantum Information: Experimental Verification of the QMM Hypothesis \|date=2025 \|class=physics.gen-ph }}</ref> * '''2025 (January).''' ''Annals of Physics'' publishes the '''Geometry-Information Duality (GID)''' paper, providing the theoretical foundation that links local imprint entropy to space-time curvature and unifies QMM with black-hole thermodynamics.<ref name="GID">{{cite journal \|last=Neukart \|first=Florian \|title=Geometry–Information Duality and Black-Hole Entropy \|journal=Annals of Physics \|year=2025 \|volume=475 \|pages=125392 \|doi=10.1016/j.aop.2025.125392 \|url=https://www.sciencedirect.com/science/article/pii/S0003491625001253 \|doi-access=free }}</ref>

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