Fifth force constraints from the separation of galaxy mass components

TL;DR

This paper investigates the existence of a fifth force affecting galaxies by analyzing the displacement between stellar and gas mass centroids, providing constraints on its strength and range using observational data and Bayesian modeling.

Contribution

It introduces a novel method to constrain fifth forces on galactic scales through centroid displacement analysis, incorporating screening mechanisms and Bayesian likelihood frameworks.

Findings

Evidence for a non-zero fifth force at ~2 Mpc scale with 6.6σ significance.

No significant detection of unscreened fifth force across tested ranges.

Upper limits on fifth force strength vary from 10^{-1} to a few times 10^{-4} depending on scale.

Abstract

One of the most common consequences of extensions to the standard models of particle physics or cosmology is the emergence of a fifth force. While generic fifth forces are tightly constrained at Solar System scales and below, they may escape detection by means of a screening mechanism which effectively removes them in dense environments. We constrain the strength $\Delta G/G_N$ and range $\lambda_C$ of a chameleon- or symmetron-screened fifth force with Yukawa coupling -- as well as an unscreened fifth force with differential coupling to galactic mass components -- by searching for the displacement it predicts between galaxies' stellar and gas mass centroids. Taking data from the Alfalfa HI survey, identifying galaxies' gravitational environments with the maps of Desmond et al. (2018a) and forward-modelling with a Bayesian likelihood framework, we find $6.6\sigma$ evidence for $\Delta G>0$ at $\lambda_C \simeq 2$ Mpc, with $\Delta G/G_N = 0.025$ at maximum-likelihood. A similar fifth-force model without screening gives no increase in likelihood over the case $\Delta G = 0$ for any $\lambda_C$. Although we validate these results by several methods, we do not claim screened modified gravity to provide the only possible explanation for the signal: this would require knowing that "galaxy formation" physics could not be responsible. We show also the results of a more conservative -- though less well motivated -- noise model which yields only upper limits on $\Delta G/G_N$, ranging from $\sim10^{-1}$ for $\lambda_C \simeq 0.5$ Mpc to $\sim \: \text{few} \times 10^{-4}$ at $\lambda_C \simeq 50$ Mpc. We show how these constraints may be improved by future galaxy surveys and identify the key features of an observational programme for directly constraining fifth forces on galactic scales. This paper provides a complete description of the analysis summarised in Desmond et al. (2018b).