Towards a new generalized space expansion dynamics applied to the rotation of galaxies and Tully Fisher law

TL;DR

This paper introduces a new generalized space expansion dynamics based on classical Newtonian physics, explaining galactic rotation and the Tully Fisher law without exotic matter, by proposing a universal acceleration linked to space expansion.

Contribution

It presents a novel approach using a universal expansion law and a new acceleration to explain galactic dynamics and the Tully Fisher law without dark matter or modified gravity theories.

Findings

Good description of galactic transverse velocity variations

Estimation of the Tully Fisher acceleration coefficient

Expansion proportional to the square root of local density

Abstract

Up to now, the rotational velocities of galaxies are not clearly understood and the experimental Tully Fisher rule, linking the total galactic mass to the fourth power of the velocity, through an acceleration coefficient of about 10-10 m/s2 has not found a deep theoretical explanation. Tentative proposals (MOND theory of a modified Newton s law and extraneous dark matter) do not bring a definite clarification. We propose here a new approach to this problem, without exotic matter and using the classical Newton force. But we introduce a new additional universal acceleration, which could represent a universal expansion law valid at the scale level of a galaxy. We show that this hypothesis leads to a good description of the observed variations of the galactic transverse velocity. It can be considered as a consequence of the Scale Expansion Cosmos theory (SEC) introduced by J. Masreliez, but we postulate that the space expansion acceleration universally applies at any scale. We obtain a formal derivation of the Tully Fisher law, linking the constant galactic transverse velocity to its total mass, via the universal minimum acceleration. We derive a good estimate of the TF acceleration coefficient and show that expansion should be proportional to the square root of the local volumic mass density. Our conjecture is in fact a new dynamics principle which could be applied to many other physical problems at different scales. Applying it to the range of the solar planet system confirms the well known Kepler laws, at least as a valid approximation for the order of magnitude of the solar system.