Quantum Gravity Emergence from Entanglement in a Multi-Fold Universe
Autor: | Maes, Stephane H. |
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Přispěvatelé: | UCLOUVAIN BNTE LOUVAIN LA NEUVE BEL, Partenaires IRSTEA, Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA) |
Jazyk: | angličtina |
Rok vydání: | 2020 |
Předmět: |
fractional spacetime
Quantum Gravity Torsion standard model multi-fold mappings Fractal Spacetime beyond the standard model Grand Unification Theories gravity fluctuations Yang Mills Viability Quantum Entanglement Spacetime as network of black holes SM_G String theory GUT Mass Generation Theory of Everything Right-handed neutrinos Equivalence Principle factual AdS/CFT correspondence new physics [PHYS.HTHE]Physics [physics]/High Energy Physics - Theory [hep-th] Strong CP violation Physics E/G Conjecture Recovery of General Relativity Einstein Podolsky Rosen M-Theory Multi-fold Theory 2D spacetime Dark Energy Life cycle of black holes multi-fold mechanisms Unification Quantum Geometry CFT/AdS Correspondence conjecture spacetime as network of microscopic black holes Quantum Computing Proton Decay Problem Magnetic Monopole problem non-commutative Discrete Spacetime General Relativity Black Holes Gravity Ultimate Unification microscopic black holes quantum entanglement CFT Lorentz invariance Supergravity particle as microscopic black hole General Relativity and Quantum Cosmology spacetime reconstruction attractive effective potential Spin fractal ER=EPR Dark matter Standard model with gravity emergence GR=QM Number of Fermion generations per family AdS Curvature Weak Gravity Conjecture No singularities random walks Inflation Strong CP Problem Noncommutative Geometry Loop Quantum Gravity Neutrinos mass problems EPR Mass Gap Problem Path Integrals Big Bounce Superstrings 3 generations of Fermions |
Zdroj: | Stephane H. Maes |
Popis: | We start from a hypothetical multi-fold universe UMF , where the propagation of everything is slower or equal to the speed of light and where entanglement extends the set of paths available to Path Integrals. This multifold mechanism enables EPR (Einstein-Podolsky-Rosen) “spooky actions at distance” to result from local interactions in the resulting folds. It produces gravity-like attractive effective potentials in the spacetime, between entangled entities, that are caused by the curvature of the folds. When quantized, multi-folds correspond to gravitons and they are enablers of EPR entanglement. Gravity emerges non-perturbative and covariant from EPR entanglement between virtual particles surrounding an entity. In UMF, we encounter mechanisms that predict gravity fluctuations when entanglement is present, including in macroscopic entanglements. Besides providing a new perspective on quantum gravity, when added to the Standard Model as (SMG), with non-negligible affects at its scales, and to the Standard Cosmology, UMF can contribute explanations of several open questions and challenges. It also clarifies some relationships and challenges met by other quantum gravity models and Theories of Everything. It leads to suggestions for these works. We also reconstruct the spacetime of UMF, starting from the random walks of particles in an early spacetime. UMF now appears as a noncommutative, discrete, yet Lorentz symmetric, spacetime that behaves roughly 2-Dimensional at Planck scales, when it is a graph of microscopic Planck size black holes on a random walk fractal structure left by particles that can also appear as microscopic black holes. Of course, at larger scales, spacetime appears 4-D, where we are able to explain curvature and recover Einstein’s General Relativity. We also discover an entanglement gravity-like contributions and massive gravity at very small scales. This is remarkable considering that no Hilbert Einstein action, or variations expressing area invariance, were introduced. Our model also explains why semi classical approaches can work till way smaller scale than usually expected and present a new view on an Ultimate Unification of all forces, at very small scales. We also explore opportunities for falsifiability and validation of our model, as well as ideas for futuristic applications, that may be worth considering, if UMF was a suitable model for our universe Ureal . It is the original paper. Cite as: Cite as: Stephane H. Maes, (2020-2022) "Quantum Gravity Emergence from Entanglement in a Multi-Fold Universe", HIJ, Vol 2, No 4, pp 136-219, Dec 2022, https://doi.org/10.55672/hij2022pp136-219, https://shmaesphysics.wordpress.com/2020/06/09/paper-published-as-preprint-quantum-gravity-emergence-from-entanglement-in-a-multi-fold-universe/, https://shmaesphysics.wordpress.com/2022/11/09/quantum-gravity-emergence-from-entanglement-in-a-multi-fold-universe-2/, and viXra:2006.0088, (June 9, 2020). |
Databáze: | OpenAIRE |
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