International Journal of Astrophysics and Space Science

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Planckian Energy-Mass Source and the Dynamics of the Universe: Phenomenology

Received: 30 May 2014    Accepted: 20 June 2014    Published: 30 June 2014
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Abstract

A phenomenological model of the dynamics of the Universe is suggested as an alternative of the standard model dynamics whose inadequacy is borne out by the catastrophic difference – over 40 orders of magnitude – between the cosmological constant obtained on the basis of the standard cosmological model and that derived from experimental data. The key factor in the solution of the complex of problems unresolvable within the scope of the standard theory, the problems associated with the establishment of the essence of dark energy and dark matter included, is the abandonment of the notions of the Big Bang involving the momentary generation of matter and adoption of the hypothesis for the existence of an energy-mass source of Planckian power that originated at the instant the Big Bang took place, the energy of this source being constantly generated in and evenly distributed over every element of the already originated or originating space. Possible experimental investigations aimed at gaining an insight into the issues concerning the dynamics of the Universe are discussed.

DOI 10.11648/j.ijass.20140203.11
Published in International Journal of Astrophysics and Space Science (Volume 2, Issue 3, June 2014)
Page(s) 33-45
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This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited.

Copyright

Copyright © The Author(s), 2024. Published by Science Publishing Group

Keywords

Phenomenology, Planckian Energy-Mass Source, Dynamics of the Universe, Essence of Dark Energy and Dark Matter

References
[1] Einstein A. Kosmologische Betrachtungen zur allgemeinen Relativitätheorie / Sitzung. Preus. Akad. Wiss. 1917. Bd 1, s. 142-152.
[2] Kant I. Universal Natural History and Theory of the Heavens. University of Michigan Press. 1969, 182 p.
[3] Chaadaev P.Ya. Fourth Philosophical Letter. Library Milestones. http://www.yabloko.ru/Themes/History/Chaadaev4.html
[4] Perlmutter S., Aldering G., Goldhaber G. et.al. Mea-surements of Ω and Λ from 42 High-Redshift Supernovae // Astrophys. Journal. 1999. V. 517. P. 565-586.
[5] Schmidt B.P., Suntzeff N.B., Phillips M. M., et al. The High-Z Supernova Search: Measuring Cosmic Deceleration and Global Curvature of the Un-iverse Using Type Ia Supernovae // Astrophys. J. 1998. V. 507. p. 46-63.
[6] Riess A., Filippenko A., Challis P. et al. Observational Evidence from Supernovae for an Accelerating Universe and a Cosmological Constant // Astron. J. 1998. V. 116. P. 1009-1038. ar-Xiv:astro-ph/9805201
[7] Perlmutter S. Supernovae, Dark Energy, and the Accelerating Universe. Physics Today. 2003. V. 56. N 4. P. 53-60.
[8] Rubakov V.A. Hierarchies of fundamental constants (to items Nos 16, 17, and 27 from Ginzburg’s list) // Physics – Uspekhi. Advances in Physical Sciences. 2007. V. 50. N 4. P. 390–396.
[9] Sahni V. Dark matter and dark energy // Lect. Notes Phys. 2004. V. 653. P. 141-180; ar-xiv.org/abs/astro-ph/0403324v3.
[10] Chernin A.D. Dark energy and universal antigravitation // Physics – Uspekhi. Advances in Physical Sciences. 2008. V. 51. N 3. P. 253–282.
[11] Padmanabhan T. Darker side of the Universe. 29 International Cosmic Ray Conference Pune. 2005. V. 10. P. 47-62.
[12] T. Reichhardt. Cosmolo-gists look forward to clear picture // Nature. 2003. V. 421. P. 777.
[13] Zel’dovich Ya.B. Vacuum theory: a poss-ible solution to the singularity problem of cosmology // Physics – Uspekhi. Advances in Physical Sciences. 1981. V. 24. N 3. P. 216–230.
[14] Timashev S.F. Preprint: Physical vaccum as a system manifesting itself on various scales – from nuclear physics to cosmology: http://arxiv.org/abs/1107.1799v7.
[15] Burlankov D.E. Time, space, gravity. Moscow-Izhevsk: NIC “Regular and Chaotic Dynamics”. 2006. 420 p. (in Rus-sian).
[16] Timashev S.F. // Dynamic essence of the basic relations of the special relativity theory and the origin of the fundamental interactions: phenomenology // Paper 1.
[17] Greene B. The Elegant Universe. Vintage Books. A Division of Random House, Inc. New York. 1999.
[18] Klapdor-Kleingrothaus H.V., Zuber K. Teilchenastrophysik. B.G. Teubner GmbH, Stuttgart, 1997.
[19] Lanczos C. The Variational Principles of Mechanics. Toronto: Univ. Toronto Press, 1964.
[20] Feynman R.P., Leighton R.B., Sands M. The Feynman Lectures on Physics. Vol. 1: Mechanics. Heat. Radiation. Chap. 15, § 9. Addison Wesley Reading Mass. 1966.
[21] Spergel D. N.; Verde L., Peiris H.V. et al. First Year Wilkinson Microwave Anisotropy Probe (WMAP) Observations: Determination of Cosmological Parameters // The Astrophysical Journal Supplement Series. 2003. V. 148. P. 175-194.; ar-Xiv:astro-ph/0302209.
[22] Perelman G. The entropy formula for the Ricci flow and its geometric applications. http://arXiv:math/0211159v1.
[23] Brooks D.W.C., Botter T, Schreppler S. Non-clqssic light generated by quantum-noise-driven cavity optomechanics // Nature. 2012. V.488. P. 476-480.
[24] Klimchitskaya G.L., Mohideen U., Mostepanenko V.M. The Casimir force between real materials: experiment and theory // Rev Mod. Phys. 2009. V. 81. P. 1827-1885.
[25] Moste-panenko V.M., Trunov N.N. The Casimir effect and its applications // Physics – Uspekhi. Advances in Physical Sciences. 1988. V. 31. N 3. P. 965–987.
[26] Dalvit D.A.R., Neto P.A.M., Mazzitelli F.D. Fluctuations, dissipation and the dynamical Casimir effect. http://arxiv.org/abs/1006.4790v2.
[27] Wilson C.M., Jo-hansson G., Pourkabirian A., Johansson J.R., Duty T., Nori F., Delsing P. Observation of the Dynamical Casimir Effect in a Superconducting Circuit. http://arxiv.org/pdf/1105.4714v1.
[28] Weinberg S. Cosmology. Oxford: University Press. 2008, 593 p.
[29] Okun' L.B. Physics of elementary particles. Moscow: Nauka. 1984, 224 p. (in Rus-sian).
[30] Chand H., Srianand R., Petitjean, Aracil B. Probing the cosmological variation of the fine structure constant: Results based on the VLT-UVES sample; http://arXiv:astro-ph/0401094v1.
[31] Zel'dovich Ya.B., Novikov I.D. The Structure and Evolution of the Universe. Chicago: University of Chicago, 1983.
[32] Delvin M.J., Ade P.A.R., Aretxaga I., et al. Over half of the far-infrared background light comes from galaxies at z ≥ 1.2 // Nature. 2009. V.458. P. 737-739.
[33] Nagao T., Maiolino R., Breuck C. De et al. ALMA reveals a chemi-cally evolved submillimeter galaxy at z = 4.76 // As-tronomy and Astrophysics. 2012. V. 542. L34-38; ar-Xiv:1205.4834v2 [astro-ph.CO] 29 May 2012.
[34] Hogan C.J. Ripples of early starlight // Nature. 2007. V. 445. P. 37.
[35] Amanullah R., Lidman C., Rubin D., et al. Spectra and Hubble Space Telescope Light Curves of Six Type Ia Supernovae at 0.511 < z < 1.12 and the Union2 Compilation // The Astrophysical Journal, Volume 716, Issue 1, pp. 712-738 (2010).
[36] Plebański J., Krasiński A. An introduction to General Relativity and cosmology. Cambridge: Cambridge University Press. 2006, 534 p.
[37] Sta-robinsky A.A. How to determine an effective potential for a variable cosmological term // JETP Lett. 1998. V. 68, No. 9-10. P. 721-726.
[38] Vilenkin A. Many worlds in one: The search for other universes. New York: Hill and Wang. 2006, 235 p.
[39] Linde A. Inflation, Quantum Cosmology and the Anthropic Principle. In: “Science and Ultimate Reality: From Quantum to Cosmos”, honoring John Wheeler’s 90th birthday. J. D. Barrow, P.C.W. Davies, & C.L. Harper eds. Cambridge: Cambridge University Press, 2003.
[40] Pen Ue-Li, Loeb A. Gamma-ray bursts from barion decay in neutron stars. // The Astrophys. Journal. 1998. V.509. P.537-543.
[41] Marshal H.L. The evidence in the afterglow // Nature. 2002. V.416. P.484-485.
[42] Plaga R. Rays from the dark. Nature. 2008. V. 453. P. 48-49.
[43] Reeves J.N., Watson D., Osborne J.P. et al. The signature of supernova ejecta in the ray afterglow of the -ray burst 011211. // Nature. 2002. V.416. P.512-515.
[44] Gehrels N., J. P. Norris J. P., Barthelmy J. P. et al. A new γ-ray burst classification scheme from GRB 060614. Nature. 2006. V. 444. P. 1044-1046.
[45] Bloom J. S., Perley D. A., Li W. Observations of the Naked-Eye GRB 080319B: Implications of Nature’s Brightest Explosion. The Astrophysical Journal. 2009. V. 691. N 1. P. 723-737.
[46] Quimby R.M., Aldering G, Wheeler J.C. et al. SN 2005ap: A Most Brilliant Explosion. http://arXiv:astro-ph/0709.0302v1 (Sep 2007).
[47] Blandford R.D., Helfand D.J. Will GRB 990123 Perform an Encore? http://arXiv:astro-ph/9902004v2 (Feb 1999).
[48] Cenko, S.B., et al. GRB 070125: The first long-duration gamma-ray burst in a halo environment // Astrophys. J. 2008. V. 677. P. 441- 447.
[49] Abbasi R., Abdou Y., Abu-Zayyad T. et al. An absence of neutrinos associated with cosmic-ray acceleration in γ-ray bursts // Nature. 2012. V. 484. P. 351-354].
[50] Bondi H., Gold T. The Steady-State Theory of the Expanding Universe // Monthly Notices Roy. Astron. Soc. 1948. V. 108. P. 252-270.
[51] Hoyle F. New model for the expanding Universe // Monthly Notices Royal Astron. Soc. 1948. V. 108. P. 372-382.
[52] Hoyle F., Burbidge G., Narlikar J.V. A quasi-steady state cosmological model with creation of matter // The Astrophysical Journal. 1993. V. 410. P. 437-457.
[53] Hobson M.P., Efstathiou G.; Lasenby A.N. General Relativity: An Introduction for Physicists. Cambridge University Press, 2006. 388 p.
[54] Massey R. Dark is the new black. Nature. 2009. V. 461. P. 740-741.
[55] Wel A. van der, Rix H.-W., Wuyts S., et al. The majority of compact massive galaxies at z ~ 2 are disk dominated // Astrophys. J. 2011. V. 730. P. 38-41.
[56] Dokkum Pieter van. Era of the compact disk // Nature. 2011. V. 473. P. 160-161.
[57] G.W. Erickson. Improved Lamb-shift calculation for all values of Z // Phys. Rev. Lett. 1971. V. 27. P. 780-783.
[58] Akhiezer A.I., Berestetskii. Quantum electrodynamics. Moscow: Nauka. 1981. 428 p. (in Russian).
[59] Bouwens R.J., Illingworth G.D., Labble I., Oesch P.A. et al. A candidate redshift z ≈ 10 galaxy and rapid changes in that population at an age of 500 Myr // Nature. 2011. V. 469. P.504-507.
[60] Robertson B.E., Ellis R.S., Dunlop J.S., McLure R.J., Stark D.P. Early star-forming galaxies and the reionization of the Universe // Nature. 2010. V. 468. P. 49-55.
[61] Mould J., Uddin S.A. Constraining a possible variation of G with Type Ia Supernovae; Ar-xiv:1402.1534v2 [astro-ph.CO].
[62] Wojtak W., Hansen S.H., Hjorth J. Gravitational redshift of galaxies in clusters as predicted by general relativity. Nature. 2011. V. 477. P. 567-569.
[63] Wegner G. Gravity tested on large scales. Nature. 2011. V. 477. P. 541-543.
Author Information
  • National Research Nuclear University MEPhI, Moscow, Russia; Karpov Institute of Physical Chemistry, Moscow, Russia

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    Timashev Serge. (2014). Planckian Energy-Mass Source and the Dynamics of the Universe: Phenomenology. International Journal of Astrophysics and Space Science, 2(3), 33-45. https://doi.org/10.11648/j.ijass.20140203.11

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    Timashev Serge. Planckian Energy-Mass Source and the Dynamics of the Universe: Phenomenology. Int. J. Astrophys. Space Sci. 2014, 2(3), 33-45. doi: 10.11648/j.ijass.20140203.11

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    AMA Style

    Timashev Serge. Planckian Energy-Mass Source and the Dynamics of the Universe: Phenomenology. Int J Astrophys Space Sci. 2014;2(3):33-45. doi: 10.11648/j.ijass.20140203.11

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  • @article{10.11648/j.ijass.20140203.11,
      author = {Timashev Serge},
      title = {Planckian Energy-Mass Source and the Dynamics of the Universe: Phenomenology},
      journal = {International Journal of Astrophysics and Space Science},
      volume = {2},
      number = {3},
      pages = {33-45},
      doi = {10.11648/j.ijass.20140203.11},
      url = {https://doi.org/10.11648/j.ijass.20140203.11},
      eprint = {https://download.sciencepg.com/pdf/10.11648.j.ijass.20140203.11},
      abstract = {A phenomenological model of the dynamics of the Universe is suggested as an alternative of the standard model dynamics whose inadequacy is borne out by the catastrophic difference – over 40 orders of magnitude – between the cosmological constant obtained on the basis of the standard cosmological model and that derived from experimental data. The key factor in the solution of the complex of problems unresolvable within the scope of the standard theory, the problems associated with the establishment of the essence of dark energy and dark matter included, is the abandonment of the notions of the Big Bang involving the momentary generation of matter and adoption of the hypothesis for the existence of an energy-mass source of Planckian power that originated at the instant the Big Bang took place, the energy of this source being constantly generated in and evenly distributed over every element of the already originated or originating space. Possible experimental investigations aimed at gaining an insight into the issues concerning the dynamics of the Universe are discussed.},
     year = {2014}
    }
    

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    AB  - A phenomenological model of the dynamics of the Universe is suggested as an alternative of the standard model dynamics whose inadequacy is borne out by the catastrophic difference – over 40 orders of magnitude – between the cosmological constant obtained on the basis of the standard cosmological model and that derived from experimental data. The key factor in the solution of the complex of problems unresolvable within the scope of the standard theory, the problems associated with the establishment of the essence of dark energy and dark matter included, is the abandonment of the notions of the Big Bang involving the momentary generation of matter and adoption of the hypothesis for the existence of an energy-mass source of Planckian power that originated at the instant the Big Bang took place, the energy of this source being constantly generated in and evenly distributed over every element of the already originated or originating space. Possible experimental investigations aimed at gaining an insight into the issues concerning the dynamics of the Universe are discussed.
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