Equilibrium configurations of 11eV sterile neutrinos in MONDian galaxy clusters

TL;DR

This study investigates whether 11 eV sterile neutrinos can serve as dark matter in MONDian galaxy clusters by analyzing their equilibrium distributions and phase-space limits across 30 systems, finding they are consistent with observed mass profiles.

Contribution

It provides the first detailed analysis of 11 eV sterile neutrino distributions in galaxy clusters within a MOND framework, linking cosmological and cluster-scale constraints.

Findings

All systems reach the Tremaine-Gunn limit at the center.

Fitted mass-to-light ratios are consistent with stellar population models.

11 eV sterile neutrinos are unlikely to affect spiral galaxy rotation curves.

Abstract

(Abridged) Modified Newtonian Dynamics (MOND) can fit a broad range of galaxy kinematic data, but struggles with clusters of galaxies. MONDian clusters need dark matter, and here we test the 11 eV sterile neutrino - used to fit the first three acoustic peaks of the cosmic microwave background - by investigating their equilibrium distributions in 30 groups and clusters over a wide range of temperatures. Knowing both the sterile neutrino density and velocity dispersion tells us the Tremaine-Gunn phase-space limit at all radii. We find that all 30 systems serendipitously reach the Tremaine-Gunn limit by the centre, which means a portion of the dynamical mass must always be covered by the brightest cluster galaxy. Interestingly, the typical fitted K-band mass-to-light ratio is unity and at most 1.2, which is very consistent - although leaving no margin for error - with stellar population synthesis models. Amidst the sample there are several special cases including the Coma cluster (for which dark matter was first proposed), NGC 720 (where geometrical evidence for dark matter was found) and the bullet cluster (where dark matter - of some kind - in clusters was directly proven to exist). We demonstrate that 11 eV sterile neutrinos are unlikely to influence spiral galaxy rotation curves, as they don't influence even some very massive early-types (NGC 4125 and NGC 6482). Finally, we conclude that it is intriguing that the minimum mass of sterile neutrino particle that can match the cosmic microwave background is identical to the minimum mass found here to be consistent with equilibrium configurations of MONDian clusters of galaxies.