"Calculating the Exact Experimental Density of the Dark Energy in the Cosmos Assuming a Fractal Speed of Light"
written by Mohamed S. El Naschie,
published by International Journal of Modern Nonlinear Theory and Application, Vol.3 No.1, 2014
has been cited by the following article(s):
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[1] Is There a Relationship between Energy, Amount of Information and Temperature?
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[2] Computational Fractal Logic for Quantum Physics and Cosmology
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[3] High Energy Physics and Cosmology as Computation
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[4] Kähler Dark Matter, Dark Energy Cosmic Density and Their Coupling
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[5] The Speed of the Passing of Time as Yet Another Facet of Cosmic Dark Energy
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[6] Completing Einstein's Spacetime
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[7] Cantorian-Fractal Kinetic Energy and Potential Energy as the Ordinary and Dark Energy Density of the Cosmos Respectively
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[8] Quantum Disentanglement as the Physics behind Dark Energy
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[9] 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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[10] Banach Spacetime-Like Dvoretzky Volume Concentration as Cosmic Holographic Dark Energy
International Journal of High Energy Physics, 2015
[11] From Kantian-Reinen Fernunft to the Real Dark Energy Density of the Cosmos via the Measure Concentration of Convex Geometry in Quasi Banach Spacetime
Open Journal of Philosophy, 2015
[12] Hubble Scale Dark Energy Meets Nano Scale Casimir Energy and the Rational of Their T-Duality and Mirror Symmetry Equivalence
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[13] Quantum Fractals and the Casimir-Dark Energy Duality—The Road to a Clean Quantum Energy Nano Reactor
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[14] A Resolution of the Black Hole Information Paradox via Transfinite Set Theory
World Journal of Condensed Matter Physics, 2015
[15] A Complementarity Resolution of the Black Hole Information Paradox
American Journal of Astronomy and Astrophysics, 2015
[16] From nonlocal elasticity to nonlocal spacetime and nano science
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[17] 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 …
2014
[18] Nonlocal Elasticity to Nonlocal Spacetime and Nanoscience
Bubbfil Nanotechnology, 2014
[19] 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
American Journal of Mechanics and Applications, 2014
[20] Compactified dimensions as produced by quantum entanglement, the four dimensionality of Einstein's smooth spacetime and 'tHooft's 4-ε fractal spacetime
American Journal of Astronomy & Astrophysics, 2014
[21] Cosmic Dark Energy Density from Classical Mechanics and Seemingly Redundant Riemannian Finitely Many Tensor Components of Einstein’s General Relativity
World Journal of Mechanics, 2014
[22] The meta energy of dark energy
Open Journal of Philosophy, 2014
[23] The measure concentration of convex geometry in a quasi Banach spacetime behind the supposedly missing dark energy of the cosmos
American Journal of Astronomy and Astrophysics, 2014
[24] Cosmic Dark Energy Density from Classical Mechanics and Seemingly Redundant Riemannian Finitely Many Tensor Components of Einstein's General …
2014