Crossover in extended Newtonian gravity emerging from thermodynamics

TL;DR

This paper analyzes a nonlinear field equation from thermodynamics-based extended Newtonian gravity, revealing a scale-dependent crossover between 1/r and 1/r^2 forces, with implications for dark matter.

Contribution

It provides a general analysis of the nonlinear emergent gravity field equation and demonstrates a scale-dependent force crossover relevant to dark matter.

Findings

Force exhibits unsharp crossover between 1/r and 1/r^2 outside fluid

Field energy is free from infrared divergence

Potential solutions include logarithmic potential

Abstract

In a recent paper (V\'an, P.; Abe, S. Physica A 2022, 588, 126505), it has been discovered that a scalar field coupled to a fluid and allowed to be a thermodynamic variable in consistency with the second law of thermodynamics is only gravitational and accordingly emergence of extended Newtonian gravity has been predicted. The resulting field equation for the potential of this emergent force is nonlinear and admits the logarithmic potential as a singular solution, suggesting its relevance to the dark matter conundrum. Here, a general analysis of the nonlinear field equation is performed. It is found that the emergent force field exhibits the unsharp crossover between the 1/r and 1/r^2 forces outside the fluid, depending on a spatial scale characteristic of the present theory to be observationally tested in the context of the dark matter conundrum. Then, the action functional is constructed for the potential of the emergent field and the field energy is shown to be free from an infrared divergence. A comment is also made on the difference of the present theory from MOND (modified Newtonian dynamics).