A Modified Model of the Universe Shows How Acceleration Changes Galaxy Dynamics

Jarl-Thure Eriksson^1,

¹Åbo Akademi University, Finland

Cite this paper:
Jarl-Thure Eriksson. A Modified Model of the Universe Shows How Acceleration Changes Galaxy Dynamics. International Journal of Physics. 2018; 6(2):38-46. doi: 10.12691/ijp-6-2-3

Abstract

Based on the hypothesis that the combined matter and radiation energy of the universe is balanced by an equivalent amount of negative gravitational energy, a novel formulation of the Friedmann equation is examined. The hypothesis opens new avenues for studying the evolution of the universe. The expansion, initiated by the event of a vacuum fluctuation, is driven by the continuous occurrence of new positron-electron pairs. The current acceleration of expansion, g_exp = 1,066·10^-11 m/s², emerges as a result of the study. It is mathematically shown that g_exp causes a cosmic Coriolis effect responsible for the rotary velocity deviations in the galaxies. The effect eliminates the need for dark matter. The MOND theory is explained on a purely physical basis.

Keywords:
Friedmann equation accelerating expansion of the universe Coriolis force rotational velocities of galaxies

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