QUANTUM MODIFICATION OF GENERAL RELATIVITY AND RICCI FLOW
Evgeny A. Novikov
University of California - San Diego, BioCircuits Institute, La Jolla, CA 92093 -0328; E-mail: enovikov@ucsd.edu
17 December, 2016
Abstract
Equations for the quantum modification of the general relativity (Qmoger) differ from the Einstein equations by two additional terms, which takes into account production/absorption of gravitons by the vacuum. Gravitons are shown to be ultralight and have a tiny electric dipole moment, which can help to explain the baryon asymmetry of the universe. Qmoger theory avoids initial singularity (Big Bang) and other major controversies [critical density of the universe, cosmological constant (dark energy) and inflation]. At the same time, exact analytical solution of Qmoger equations for the scale factor, without any fitting parameters, is in good quantitative agreement with cosmic observational data. The additional terms in Qmoger equations are expressed in terms of covariant divergency of the 4-velocity field. These terms are flatting the universe and are compatible with the classical curvature terms. So, the quantum effects of production/absorption of gravitons smooth out the dynamics of the universe. Qmoger theory uses the (introduced by the author) dynamics of distributed sources-sinks (DODSS), published in 2003. DODSS in turn came from desire to smooth out singularities in the obtained by the author (in 1969) general analytical solution of (1+1)-dimensional gravity. It is intuitively clear that proper DODSS can smooth out a broad class of manifolds, mathematically speaking. This led us to look at mathematical literature and, indeed, there is so called Ricci flow, introduced by R. S. Hamilton in 1982 and used by G. Perelman in 2002-2008 to proof the Poincaré conjecture ( every simply connected, closed 3-manifold is homeomorphic to the 3-sphere). A connection between DODSS (in Qmoger) and Ricci flow is discussed. The main difference, of course, is that Qmoger, besides DODSS, include also Einstein equation.
Saturday, December 17, 2016
Saturday, June 18, 2016
GRAVICOMMUNICATION, SUBJECTIVITY AND QUANTUM ENTANGLEMENT
Evgeny A. Novikov
University of California - San Diego, BioCircuits Institute,
La Jolla, CA 92093 -0328; E-mail: enovikov@ucsd.edu
Abstract
In this work gravicommunication (GC) is introduced, as a new form of communication (different from the classical gravitational waves). GC involves gravitons (particles of gravitation) and manifests itself, particularly, in our subjective experiences. This research is based on quantum modification of the general relativity. The modification includes effects of production /absorption of gravitons, which turn out to have small, but finite mass and electric dipole moment. It is shown, that such gravitons form the dipole Bose-Einstein condensate, even for high temperature. The theory (without fitting parameters) is in good quantitative agreement with cosmological observations. In this theory we got an interface between gravitons and ordinary matter, which very likely exist not only in cosmos, but everywhere, including our body and, especially, our brain. Subjective experiences are considered as a manifestation of that interface. A model of such interface is presented and some new experimentally verifiable aspects of natural neural systems are considered. According to the model, GC can be superluminal, which will solve the problem of quantum entanglement. Probable applications of these ideas include health (brain stimulation), new forms of communication, computational capabilities, energy resources and weapons. Some developed civilizations in the universe may already master GC (with various applications) and so should we.
Published in NeuroQuantology, December 2016, Volume 14, Issue 4.
References
Baez J. C. and Stay M. (2009), Physics, Topology, Logic and Computation: A Rosetta Stone, arXiv:0903.0340
Baranov M. A., Dalmonte M., Pupilto G. and Zoller P., Condensed Matter Theory of Dipolar Quantum Gases (2012), Chemical Review 112, 5012
Bohm D. & Hiley B. J., The Undivided Universe, Routledge 1993.
Chefranov S. G. & Novikov E. A., Hydrodynamic Vacuum Sources of Dark Matter Self-Generation in Accelerated Universe without Big Bang (2010), J. Exper. Theor.Phys. 111(5), 731-743 [Zhur. Eksper. Theor. Fiz.(2010),138(5), 830-843]; see also arXiv:1012.0241v1 [gr-qc].
Chynoweth K. M., Langston G. I., Holley-Bockelmann K. (2010), HI Clouds in the M81 Filament as Dark Matter Minihalos--A Phase-Space Mismatch, arXiv:1009.5679 [astro-ph.CO].
Damasio A. R., The Feeling of What Happens, Harcourt Brace & Company,1999
Freeman W. J., L. J. Rogers, M. D. Holms, D. L. Silbergelt (2000), Spatial Spectral Analysis of Human Electrocorticograms Including the Alpha and Gamma Bands, J. Neurosci. Meth. 95, 111.
Jirsa V. K., K. J. Jantzen, A. Fuchs, and J. A. Kelso (2002), Spatiotemporal forward solution of the EEG and MEG using network modeling, IEEE Trans. Med. Imaging 21(5), 497.
Kak S., R. Penrose and S. Hameroff (ed's), Quantum Physics of consciousness, Cosmology Science Publishers, Cambridge, MA, 2011.
Komisaruk B. R., Beyer-Flores C. & Whipple B., The Science of Orgasm, The John Hopkins University Press, 2006.
Novikov E. A., Mathematical Model for the Intermittency of Turbulent flow (1966), Dokl. Akad.Nauk SSSR,168, 1279 [Sov. Phys. Dokl. (1966),11, 497]
Novikov E. A., Nonlinear Evolution of Disturbances in a (1+1)-Dimensional Universe (1969), Zh. Exper. Teor. Fiz. 57,938-940 [Soviet Physcs JETP, v.30, #3, pp. 512-513, March 1970]
Novikov E. A., Scale Similarity for Random Fields (1969a), Dokl. Akad. Nauk SSSR 184, 1072 [Sov. Phys. Dokl. (1969),14(2), 104]
Novikov E. A., Intermittency and Scale Similarity in the Structure of a Turbulent Flow (1971), Prikl. Mat. Mekh. 35, 266 [Appl. Math. Mech. (1971), 35, 231]
Novikov E. A., The Effects of Intermittency on Statistical Characteristics of Turbulence and Scale Similarity of Breakdown Coefficients (1990), Phys. Fluids A 2(5), 814-820
Novikov E. A., Infinitely Divisible Distribution in Turbulence (1994), Phys. Rev. E 50(5), R3303
Novikov E. A., Dynamics of distributed sources (2003), Physics of fluids 15, L65
Novikov E. A., Towards Modeling of Consciousness (2003a), arXiv:nlin.PS/0309043
Novikov E. A., Quaternion Dynamics of the Brain (2003b), arXiv:nlin.PS/0311047
Novikov E. A., Manipulating Consciousness (2004), arXiv:nlin.PS/0403054
Novikov E. A., Modeling of Consciousness (2005), Chaos, Solitons & Fractals, 25, 1
Novikov E. A., Imaginary Fields (2005a), arXiv:nlin.PS/0502028
Novikov E. A., Algebras of Charges (2005b), arXiv:nlin.PS/0509029
Novikov E. A., Distributed Sources, Accelerated Universe, Subjectivity and Quantum Entanglement (2005c), arXiv:nlin/0511040v3.
Novikov E. A., Vacuum Response to Cosmic Stretching: Accelerated Universe and Prevention of Singularity (2006), arXiv:nlin/06080050.
Novikov E. A., Random Shooting of Entangled Particles in Vacuum (2007), arXiv:0707.3299.
Novikov E. A.,Towards Conscious Stochastic Systems (2010), arXiv:1008.0449v1[physics.gen-ph]
Novikov E. A., Age of the Universe and More (2015), J. of Cosmology 25, 13442-13452
Novikov E. A. Ultralight Gravitons with Tiny Electric Dipole Moment are Seeping from the Vacuum, (2016), Modern Physics Letters A, 31(15), 1650092 (5 pages).
Novikov E. A., Quantum Modification of General Relativity (2016a), Electron. J. Theor. Phys. 13 (35), 79-90.
Novikov E. A. & Chefranov S. G. (2011), A Quiet Cosmology and Halo Around the Visible Universe, J. of Cosmology 16, 6884-6891
Novikov E. A., Novikov A. E., Shannahof-Khalsa D., Schwartz B. and Wright J. (1997), Scale-similar activity in the brain, Phys. Rev. E 56(3), R2387.
Novikov E. A., Novikov A. E., Shannahof-Khalsa D., Schwartz B. and Wright J. (1997a), Similarity Regime in the Brain Activity, Appl. Nonl. Dyn. & Stoch. Systems (ed. Kadtke J.& Bulsara A.), p. 299-302, Amer. Inst. Phys., N. Y.
Penrose R., The Road to Reality, Jonathan Cape 2004.
Ward L. M., Dynamical Cognitive Science, Chapter 17, MIT Press, 2002
Widom A., Srivastava Y. N., Sivasubramanian S. (2011), Biological Nuclear Transmutations as a Source of Biophotons, arXiv:1102.4605 [physics.gen-ph].
Evgeny A. Novikov
University of California - San Diego, BioCircuits Institute,
La Jolla, CA 92093 -0328; E-mail: enovikov@ucsd.edu
Abstract
In this work gravicommunication (GC) is introduced, as a new form of communication (different from the classical gravitational waves). GC involves gravitons (particles of gravitation) and manifests itself, particularly, in our subjective experiences. This research is based on quantum modification of the general relativity. The modification includes effects of production /absorption of gravitons, which turn out to have small, but finite mass and electric dipole moment. It is shown, that such gravitons form the dipole Bose-Einstein condensate, even for high temperature. The theory (without fitting parameters) is in good quantitative agreement with cosmological observations. In this theory we got an interface between gravitons and ordinary matter, which very likely exist not only in cosmos, but everywhere, including our body and, especially, our brain. Subjective experiences are considered as a manifestation of that interface. A model of such interface is presented and some new experimentally verifiable aspects of natural neural systems are considered. According to the model, GC can be superluminal, which will solve the problem of quantum entanglement. Probable applications of these ideas include health (brain stimulation), new forms of communication, computational capabilities, energy resources and weapons. Some developed civilizations in the universe may already master GC (with various applications) and so should we.
Published in NeuroQuantology, December 2016, Volume 14, Issue 4.
References
Baez J. C. and Stay M. (2009), Physics, Topology, Logic and Computation: A Rosetta Stone, arXiv:0903.0340
Baranov M. A., Dalmonte M., Pupilto G. and Zoller P., Condensed Matter Theory of Dipolar Quantum Gases (2012), Chemical Review 112, 5012
Bohm D. & Hiley B. J., The Undivided Universe, Routledge 1993.
Chefranov S. G. & Novikov E. A., Hydrodynamic Vacuum Sources of Dark Matter Self-Generation in Accelerated Universe without Big Bang (2010), J. Exper. Theor.Phys. 111(5), 731-743 [Zhur. Eksper. Theor. Fiz.(2010),138(5), 830-843]; see also arXiv:1012.0241v1 [gr-qc].
Chynoweth K. M., Langston G. I., Holley-Bockelmann K. (2010), HI Clouds in the M81 Filament as Dark Matter Minihalos--A Phase-Space Mismatch, arXiv:1009.5679 [astro-ph.CO].
Damasio A. R., The Feeling of What Happens, Harcourt Brace & Company,1999
Freeman W. J., L. J. Rogers, M. D. Holms, D. L. Silbergelt (2000), Spatial Spectral Analysis of Human Electrocorticograms Including the Alpha and Gamma Bands, J. Neurosci. Meth. 95, 111.
Jirsa V. K., K. J. Jantzen, A. Fuchs, and J. A. Kelso (2002), Spatiotemporal forward solution of the EEG and MEG using network modeling, IEEE Trans. Med. Imaging 21(5), 497.
Kak S., R. Penrose and S. Hameroff (ed's), Quantum Physics of consciousness, Cosmology Science Publishers, Cambridge, MA, 2011.
Komisaruk B. R., Beyer-Flores C. & Whipple B., The Science of Orgasm, The John Hopkins University Press, 2006.
Novikov E. A., Mathematical Model for the Intermittency of Turbulent flow (1966), Dokl. Akad.Nauk SSSR,168, 1279 [Sov. Phys. Dokl. (1966),11, 497]
Novikov E. A., Nonlinear Evolution of Disturbances in a (1+1)-Dimensional Universe (1969), Zh. Exper. Teor. Fiz. 57,938-940 [Soviet Physcs JETP, v.30, #3, pp. 512-513, March 1970]
Novikov E. A., Scale Similarity for Random Fields (1969a), Dokl. Akad. Nauk SSSR 184, 1072 [Sov. Phys. Dokl. (1969),14(2), 104]
Novikov E. A., Intermittency and Scale Similarity in the Structure of a Turbulent Flow (1971), Prikl. Mat. Mekh. 35, 266 [Appl. Math. Mech. (1971), 35, 231]
Novikov E. A., The Effects of Intermittency on Statistical Characteristics of Turbulence and Scale Similarity of Breakdown Coefficients (1990), Phys. Fluids A 2(5), 814-820
Novikov E. A., Infinitely Divisible Distribution in Turbulence (1994), Phys. Rev. E 50(5), R3303
Novikov E. A., Dynamics of distributed sources (2003), Physics of fluids 15, L65
Novikov E. A., Towards Modeling of Consciousness (2003a), arXiv:nlin.PS/0309043
Novikov E. A., Quaternion Dynamics of the Brain (2003b), arXiv:nlin.PS/0311047
Novikov E. A., Manipulating Consciousness (2004), arXiv:nlin.PS/0403054
Novikov E. A., Modeling of Consciousness (2005), Chaos, Solitons & Fractals, 25, 1
Novikov E. A., Imaginary Fields (2005a), arXiv:nlin.PS/0502028
Novikov E. A., Algebras of Charges (2005b), arXiv:nlin.PS/0509029
Novikov E. A., Distributed Sources, Accelerated Universe, Subjectivity and Quantum Entanglement (2005c), arXiv:nlin/0511040v3.
Novikov E. A., Vacuum Response to Cosmic Stretching: Accelerated Universe and Prevention of Singularity (2006), arXiv:nlin/06080050.
Novikov E. A., Random Shooting of Entangled Particles in Vacuum (2007), arXiv:0707.3299.
Novikov E. A.,Towards Conscious Stochastic Systems (2010), arXiv:1008.0449v1[physics.gen-ph]
Novikov E. A., Age of the Universe and More (2015), J. of Cosmology 25, 13442-13452
Novikov E. A. Ultralight Gravitons with Tiny Electric Dipole Moment are Seeping from the Vacuum, (2016), Modern Physics Letters A, 31(15), 1650092 (5 pages).
Novikov E. A., Quantum Modification of General Relativity (2016a), Electron. J. Theor. Phys. 13 (35), 79-90.
Novikov E. A. & Chefranov S. G. (2011), A Quiet Cosmology and Halo Around the Visible Universe, J. of Cosmology 16, 6884-6891
Novikov E. A., Novikov A. E., Shannahof-Khalsa D., Schwartz B. and Wright J. (1997), Scale-similar activity in the brain, Phys. Rev. E 56(3), R2387.
Novikov E. A., Novikov A. E., Shannahof-Khalsa D., Schwartz B. and Wright J. (1997a), Similarity Regime in the Brain Activity, Appl. Nonl. Dyn. & Stoch. Systems (ed. Kadtke J.& Bulsara A.), p. 299-302, Amer. Inst. Phys., N. Y.
Penrose R., The Road to Reality, Jonathan Cape 2004.
Ward L. M., Dynamical Cognitive Science, Chapter 17, MIT Press, 2002
Widom A., Srivastava Y. N., Sivasubramanian S. (2011), Biological Nuclear Transmutations as a Source of Biophotons, arXiv:1102.4605 [physics.gen-ph].
Saturday, April 2, 2016
DICTATORS ARE OUT OF FASHION (IN SCIENCE, AS WELL AS IN POLITICS)
Evgeny A. Novikov
University of California - San Diego, BioCircuits Institute,
La Jolla, CA 92093 -0328; E-mail: enovikov@ucsd.edu
04. 02. 2016
Abstract
At the current level of development of the human society with global communication, the dictatorship should be abandoned not only in politics, but also in science. Particularly, the dictatorship of concept of the imaginary Big Bang with all its controversies (critical density of the universe, dark energy, inflation etc.) may lead to real catastrophe, not only in science, but for the whole human society.
Evgeny A. Novikov
University of California - San Diego, BioCircuits Institute,
La Jolla, CA 92093 -0328; E-mail: enovikov@ucsd.edu
04. 02. 2016
Abstract
At the current level of development of the human society with global communication, the dictatorship should be abandoned not only in politics, but also in science. Particularly, the dictatorship of concept of the imaginary Big Bang with all its controversies (critical density of the universe, dark energy, inflation etc.) may lead to real catastrophe, not only in science, but for the whole human society.
Saturday, January 30, 2016
GRAVICOMMUNICATION
GRAVICOMMUNICATION (GC)
Evgeny A. Novikov
University of California - San Diego, BioCircuits Institute,
La Jolla, CA 92093 -0328; E-mail: enovikov@ucsd.edu
Abstract
In this work gravicommunication (GC) is introduced, as a new form of communication (different from the gravitational waves), which involves gravitons (elementary particles of gravitation). This research is based on quantum modification of the general relativity. The modification includes effects of production /absorption of gravitons, which turn out to have small, but finite mass and electric dipole moment. It is shown, that such gravitons form the dipole Bose-Einstein condensate, even for high temperature. The theory (without fitting parameters) is in good quantitative agreement with cosmological observations. In this theory we got an interface between gravitons and ordinary matter, which very likely exist not only in cosmos, but everywhere, including our body and, especially, our brain. Subjective experiences are considered as a manifestation of that interface. A model of such interface is presented and some new experimentally verifiable aspects of natural neural systems are considered. According to the model, GC can be superluminal, which will solve the problem of quantum entanglement. Probable applications of these ideas include health (brain stimulation), new forms of communication, computational capabilities, energy resources and weapons. Potential social consequences of these developments can be comparable with the effects of discovery and applications of electricity. Some developed civilizations in the universe may already master gravicommunication (with various applications) and so should we.
Evgeny A. Novikov
University of California - San Diego, BioCircuits Institute,
La Jolla, CA 92093 -0328; E-mail: enovikov@ucsd.edu
Abstract
In this work gravicommunication (GC) is introduced, as a new form of communication (different from the gravitational waves), which involves gravitons (elementary particles of gravitation). This research is based on quantum modification of the general relativity. The modification includes effects of production /absorption of gravitons, which turn out to have small, but finite mass and electric dipole moment. It is shown, that such gravitons form the dipole Bose-Einstein condensate, even for high temperature. The theory (without fitting parameters) is in good quantitative agreement with cosmological observations. In this theory we got an interface between gravitons and ordinary matter, which very likely exist not only in cosmos, but everywhere, including our body and, especially, our brain. Subjective experiences are considered as a manifestation of that interface. A model of such interface is presented and some new experimentally verifiable aspects of natural neural systems are considered. According to the model, GC can be superluminal, which will solve the problem of quantum entanglement. Probable applications of these ideas include health (brain stimulation), new forms of communication, computational capabilities, energy resources and weapons. Potential social consequences of these developments can be comparable with the effects of discovery and applications of electricity. Some developed civilizations in the universe may already master gravicommunication (with various applications) and so should we.
QUANTUM MODIFICATION OF GENERAL RELATIVITY
QUANTUM MODIFICATION OF GENERAL RELATIVITY
Evgeny A. Novikov
University of California - San Diego, BioCircuits Institute,
La Jolla, CA 92093 -0328; E-mail: enovikov@ucsd.edu
Abstract
This work is based on modification of the general relativity with two additional terms in the Einstein equations. The additional terms give macroscopic description of the quantum effects of production /absorption of matter by the vacuum. The theory (without fitting parameters and without hypothesis of inflation) is in good quantitative agreement with cosmological observations (SnIa, SDSS-BAO and reduction of acceleration of the expanding universe). In this theory, there is no Big Bang at the beginning, but some local bangs during the evolution are probable. Also, there is no critical density of the universe and, therefore, no dark energy (no need in the cosmological constant). Based on exact Gaussian solution for the scale factor, it is shown that an effective age of the universe is about 327 billion years. Production of primary dark matter particles (possibly, gravitons) have started 43 billion years later. It is shown that characteristic distance between particles is much smaller than the thermal de Brogle wavelength, so that quantum effects, including formation of the Bose-Einstein condensate, can dominate, even for high temperature. "Ordinary" matter was synthesized from dark matter (with estimated small electric dipole moment (EDM)) in galaxies. Supplementary exact solutions are obtained for various ranges of parameters. From the theory we get an interface between dark and ordinary matter (IDOM), which very likely exist not only in cosmos, but everywhere, including our body and our brain.
Key words: modification of general relativity; cosmology; age of the universe; dark matter (gravitons); interface between dark and ordinary matter.
Published in Electronic Journal of Theoretical Physics v.13, No. 35 (2016) 79-90.
Evgeny A. Novikov
University of California - San Diego, BioCircuits Institute,
La Jolla, CA 92093 -0328; E-mail: enovikov@ucsd.edu
Abstract
This work is based on modification of the general relativity with two additional terms in the Einstein equations. The additional terms give macroscopic description of the quantum effects of production /absorption of matter by the vacuum. The theory (without fitting parameters and without hypothesis of inflation) is in good quantitative agreement with cosmological observations (SnIa, SDSS-BAO and reduction of acceleration of the expanding universe). In this theory, there is no Big Bang at the beginning, but some local bangs during the evolution are probable. Also, there is no critical density of the universe and, therefore, no dark energy (no need in the cosmological constant). Based on exact Gaussian solution for the scale factor, it is shown that an effective age of the universe is about 327 billion years. Production of primary dark matter particles (possibly, gravitons) have started 43 billion years later. It is shown that characteristic distance between particles is much smaller than the thermal de Brogle wavelength, so that quantum effects, including formation of the Bose-Einstein condensate, can dominate, even for high temperature. "Ordinary" matter was synthesized from dark matter (with estimated small electric dipole moment (EDM)) in galaxies. Supplementary exact solutions are obtained for various ranges of parameters. From the theory we get an interface between dark and ordinary matter (IDOM), which very likely exist not only in cosmos, but everywhere, including our body and our brain.
Key words: modification of general relativity; cosmology; age of the universe; dark matter (gravitons); interface between dark and ordinary matter.
Published in Electronic Journal of Theoretical Physics v.13, No. 35 (2016) 79-90.
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