Energy density profile inspired by noncommutativity

TL;DR

This paper investigates the astrophysical implications of an energy density inspired by noncommutativity, analyzing its effects on stellar models and galaxy rotation curves, and comparing results with traditional dark matter models.

Contribution

It introduces a novel energy density profile inspired by noncommutativity and applies it to stellar and galactic dynamics, providing constraints and comparisons with existing dark matter models.

Findings

Derived parameter ranges for galaxy rotation curves consistent with observations.

Compared noncommutative-inspired model with traditional dark matter profiles.

Estimated surface density values aligning with observational data.

Abstract

An important consequence which comes from noncommutativity (NC) is undoubtedly the energy density characterized by a microscopic free parameter; indeed a Trans-Planckian parameter. However, its functional form is an interesting and useful equation which can be analyzed in astrophysical scenarios giving now astrophysical constraints. In this sense, this paper is devoted to explore the astrophysical consequences of an energy density with the same functional form of NC; mainly in stellar dynamics and rotation curves of galaxies. We start exploring toy models of stars with incompressible and polytropic fluids respectively, with the addition and coexistence with this new fluid. In both cases, we propose an appropriate constriction based on the difference between a correct and an anomalous behavior. As a complement, we explore the rotation curves of galaxies assuming that the halo is a fluid with the same characteristic of a NC equation, obtaining the range of values for the free parameter through the analysis of eighteen LSB galaxies. Our results are compared with traditional models studied in literature like Pseudoisothermal (PISO), Navarro-Frenk-White (NFW), Burkert and WaveDM dark matter models. Finally, we have computed the surface density, $\rho_i r_i$ for each dark matter model, where $i$ is for PISO, NFW, Burkert, WaveDM and NC macroscopic version. In the later case, following the results found using SPARC galaxy catalog, we have found a theoretical value of $116.97 M_\odot$ pc$^{-2}$ while the data analysis gives us a value of $144.21 M_\odot$ pc$^{-2}$.