[1]
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Quantum Entanglement and Quantum Disentanglement in Connection to the Ordinary and Dark Energy of Cosmos
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[2]
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Fluid Turbulence Road to Quantum Cantorian Spacetime Via Nested Solitonic Golden Eddies Chaos Implied by Batchelor's Law-A Possible Rationale for the …
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2020 |
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[3]
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Massive Gravity from a Fractal-Cantorian Spacetime Perspective
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2020 |
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[4]
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A fundamentally fractal universe from Einstein, Kaluza-Klein, Witten and Vafa‟ s spacetime
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2019 |
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[5]
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A Fundamentally Fractal Universe from Einstein, Kaluza-Klein, Witten and Vafa's Space-Time
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2019 |
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[6]
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From Nikolay Umov E= kmc2 via Albert Einstein's E= γmc2 to the Dark Energy Density of the Cosmos E=(21/22) mc2
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2018 |
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[7]
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El Naschie,“From Nikolay Umov= 2 E kmc via Albert Einstein's γ= 2 E mc to the dark energy density of the cosmos()= 2 21 22 E mc.”
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2018 |
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[8]
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From Nikolay Umov E=kmc2 via Albert Einstein's E=γmc2 to the Dark Energy Density of the Cosmos E=(21/22)mc2
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2018 |
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[9]
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World Formula Interpretation of E= mc2
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2018 |
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[10]
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Density of the Cosmos () E mc 2 21 22=
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2018 |
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[11]
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The Physics, Mathematics and Common Sense of Cosmic Dark Energy and Spacetime Extra Dimensions
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2017 |
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[12]
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'tHooft's Renormalon: Experimental and Number Theoretical Arguments for Physical Existence
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2017 |
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[13]
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The Self Similar Newton's Energ
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2016 |
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[14]
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Kähler Dark Matter, Dark Energy Cosmic Density and Their Coupling
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2016 |
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[15]
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The Speed of the Passing of Time as Yet Another Facet of Cosmic Dark Energy
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2016 |
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[16]
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Completing Einstein's Spacetime
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2016 |
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[17]
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Cantorian-Fractal Kinetic Energy and Potential Energy as the Ordinary and Dark Energy Density of the Cosmos Respectively
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2016 |
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[18]
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Quantum Disentanglement as the Physics behind Dark Energy
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2016 |
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[19]
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Cosserat-Cartan and de Sitter-Witten Spacetime Setting for Dark Energy
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Quantum Matter,
2016 |
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[20]
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Quantum Dark Energy from the Hyperbolic Transfinite Cantorian Geometry of the Cosmos
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Natural Science,
2016 |
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[21]
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On a fractal version of Witten's M-Theory
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International Journal of Astronomy and Astrophysics,
2016 |
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[22]
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Negative Norms in Quantized Strings as Dark Energy Density of the Cosmos
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World Journal of Condensed Matter Physics,
2016 |
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[23]
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Einstein's Dark Energy via Similarity Equivalence,'tHooft Dimensional Regularization and Lie Symmetry Groups
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International Journal of Astronomy and Astrophysics,
2016 |
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[24]
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Max Planck Half Quanta as a Natural Explanation for Ordinary and Dark Energy of the Cosmos
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2016 |
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[25]
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High Energy Physics and Cosmology as Computation
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2016 |
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[26]
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Computational Fractal Logic for Quantum Physics and Cosmology
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2016 |
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[27]
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From Kantian-Reinen Fernunft to the Real Dark Energy Density of the Cosmos via the Measure Concentration of Convex Geometry in Quasi Banach …
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2015 |
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[28]
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An Exact Mathematical Picture of Quantum Spacetime
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Advances in Pure Mathematics,
2015 |
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[29]
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Hubble Scale Dark Energy Meets Nano Scale Casimir Energy and the Rational of Their T-Duality and Mirror Symmetry Equivalence
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World Journal of Nano Science and Engineering,
2015 |
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[30]
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Quantum Fractals and the Casimir-Dark Energy Duality—The Road to a Clean Quantum Energy Nano Reactor
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Journal of Modern Physics,
2015 |
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[31]
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A Casimir-Dark Energy Nano Reactor Design—Phase One
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Natural Science,
2015 |
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[32]
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A Resolution of the Black Hole Information Paradox via Transfinite Set Theory
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World Journal of Condensed Matter Physics,
2015 |
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[33]
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On El Naschie's Fractal-Cantorian Space-Time and Dark Energy—A Tutorial Review
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Natural Science,
2015 |
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[34]
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Dark energy and its cosmic density from Einstein's relativity and gauge fields renormalization leading to the possibility of a new 'tHooft quasi particle
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2015 |
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[35]
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The Casimir Effect as a Pure Topological Phenomenon and the Possibility of a Casimir Nano Reactor–A Preliminary Conceptual Design
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2015 |
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[36]
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The Casimir effect as a pure topological phenomenon and the possibility of a Casimir nano reactor—A preliminary design
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2015 |
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[37]
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The Casimir effect as a pure topological phenomenon and the possibility of a Casimir nano reactor—a preliminary conceptual design
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American Journal of Nano Research and Applications,
2015 |
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[38]
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A Complementarity Resolution of the Black Hole Information Paradox
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American Journal of Astronomy and Astrophysics,
2015 |
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[39]
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From Kantian-Reinen Vernunft to the Real Dark Energy Density of the Cosmos via the Measure Concentration of Convex Geometry in Quasi Banach Spacetime
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2015 |
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[40]
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From Kantian-Reinen Fernunft to the Real Dark Energy Density of the Cosmos via the Measure Concentration of Convex Geometry in Quasi Banach …
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2015 |
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[41]
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Naschie: From E= mc2 to E= mc2/22—A Short Account of the Most Famous Equation in Physics and Its Hidden Quantum Entanglement Origin
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2014 |
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[42]
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Ji-Huan He
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2014 |
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[43]
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From E = mc2 to E = mc2/22—A Short Account of the Most Famous Equation in Physics and Its Hidden Quantum Entanglement Origin
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2014 |
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[44]
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Telaah Koreksi Teori Relativitas Khusus (TRK) Einstein
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2014 |
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[45]
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Hardy's Entanglement as the Ultimate Explanation for the Observed Cosmic Dark Energy and Accelerated Expansion
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2014 |
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[46]
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Deriving E= mc2/22 of Einstein's ordinary quantum relativity energy density from the Lie symmetry group SO (10) of grand unification of all fundamental forces …
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2014 |
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[47]
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Why E Is Not Equal to mc2
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2014 |
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[48]
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Entanglement of E8E8 Exceptional Lie Symmetry Group Dark Energy, Einstein's Maximal Total Energy and the Hartle-Hawking No Boundary Proposal as the …
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2014 |
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[49]
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Pinched Material Einstein Space-Time Produces Accelerated Cosmic Expansion
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International Journal of Astronomy and Astrophysics,
2014 |
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[50]
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Electromagnetic—Pure Gravity Connection via Hardy's Quantum Entanglement
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Journal of Electromagnetic Analysis and Applications,
2014 |
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[51]
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Why E Is Not Equal to mc 2
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Journal of Modern Physics,
2014 |
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[52]
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From E= mc 2 to E= mc 2/22—A Short Account of the Most Famous Equation in Physics and Its Hidden Quantum Entanglement Origin
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2014 |
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[53]
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Logarithmic running of 't Hooft-Polyakov monopole to dark energy
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International Journal of High Energy Physics,
2014 |
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[54]
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Deriving E= mc 2/22 of Einstein’s ordinary quantum relativity energy density from the Lie symmetry group SO (10) of grand unification of all fundamental forces and without quantum mechanics
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American Journal of Mechanics and Applications,
2014 |
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[55]
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Rindler space derivation of dark energy
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Journal of Modern Physics and Applications,
2014 |
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[56]
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A Tutorial Review on Fractal Spacetime and Fractional Calculus
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International Journal of Theoretical Physics,
2014 |
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[57]
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Asymptotically safe pure gravity as the source of dark energy of the vacuum
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Astrophysics and Space Science,
2014 |
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[58]
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The meta energy of dark energy
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Open Journal of Philosophy,
2014 |
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[59]
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Calculating the Exact Experimental Density of the Dark Energy in the Cosmos Assuming a Fractal Speed of Light
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International Journal of Modern Nonlinear Theory and Application,
2014 |
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[60]
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From Chern-Simon, Holography and Scale Relativity to Dark Energy
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Journal of Applied Mathematics and Physics,
2014 |
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[61]
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The Gap Labelling Integrated Density of States for a Quasi Crystal Universe Is Identical to the Observed 4.5 Percent Ordinary Energy Density of the Cosmos
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Natural Science,
2014 |
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[62]
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Cosmic Dark Energy from 't Hooft's Dimensional Regularization and Witten's Topological Quantum Field Pure Gravity
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Journal of Quantum Information Science,
2014 |
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[63]
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From E= mc2 to E= mc2/22—A Short Account of the Most Famous Equation in Physics and Its Hidden Quantum Entanglement Origin
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Journal of Quantum Information Science,
2014 |
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[64]
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Entanglement of E8E8 Exceptional Lie Symmetry Group Dark Energy, Einstein’s Maximal Total Energy and the Hartle-Hawking No Boundary Proposal as the Explanation for Dark Energy
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World Journal of Condensed Matter Physics,
2014 |
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[65]
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The measure concentration of convex geometry in a quasi Banach spacetime behind the supposedly missing dark energy of the cosmos
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American Journal of Astronomy and Astrophysics,
2014 |
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[66]
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Deriving E= mc2/22 of Einstein's ordinary quantum relativity energy density from the Lie symmetry group SO (10) of grand unification of all fundamental …
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American Journal of Mechanics & Applications,
2014 |
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[67]
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On the missing 95.5 percent dark energy lost in the collapse of Hawking-Hartle quantum wave of the universe
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Fractal Spacetime and Noncommutative Geometry in Quantum and High Energy Physics,
2013 |
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[68]
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Chaotic fractals at the root of relativistic quantum physics and cosmology
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International Journal of Modern Nonlinear Theory and Application,
2013 |
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[69]
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Dark energy explained via the Hawking-Hartle quantum wave and the topology of cosmic crystallography
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International Journal of Astronomy and Astrophysics,
2013 |
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[70]
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Experimentally based theoretical arguments that Unruh's temperature, Hawking's vacuum fluctuation and Rindler's wedge are physically real
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2013 |
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[71]
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Dark energy from Kaluza-Klein spacetime and Noether's theorem via lagrangian multiplier method
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Journal of Modern Physics,
2013 |
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[72]
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Nash embedding of Witten's M-theory and the Hawking-Hartle quantum wave of dark energy
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Journal of Modern Physics,
2013 |
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[73]
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The Missing Dark Energy of the Cosmos from Light Cone Topological Velocity and Scaling of the Planck Scale
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Open Journal of Microphysics,
2013 |
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[74]
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The Three Page Guide to the Most Important Results of MS El Naschie's Research in E-Infinity Quantum Physics and Cosmology
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Open Journal of Microphysics,
2013 |
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[75]
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Quantum gravity and dark energy using fractal Planck scaling
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Journal of Modern Physics,
2013 |
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[76]
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Experimentally Based Theoretical Arguments that Unruh's Temperature, Hawkings's Vacuum Fluctuation and Rindler's Wedge Are Physically Real
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American Journal of Modern Physics? ,
2013 |
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