Modified Gravity and the Origin of the Excess Radio Galaxy Number-Count Dipole

TL;DR

This paper explores whether Scalar--Tensor--Vector Gravity (STVG-MOG) can explain the observed excess in the cosmic radio galaxy number-count dipole, which exceeds standard model expectations, by modifying gravitational response on ultra-large scales.

Contribution

It proposes a scale- and time-dependent gravitational coupling in STVG-MOG that amplifies large-scale structure responses, offering a potential explanation for the dipole excess beyond standard cosmology.

Findings

STVG-MOG can increase large-scale structure contribution to the radio dipole.

The model preserves standard cosmological evolution at early times and small scales.

The radio dipole anomaly serves as a new test for gravitational physics on cosmic scales.

Abstract

Recent analyses of wide-area radio-galaxy surveys have reported a statistically significant excess in the cosmic number-count dipole, with an amplitude exceeding the purely kinematic expectation of the standard $\Lambda$CDM model by a factor of $\sim 3$--$4$, quoted at a significance level of up to $5.4\sigma$. While residual observational systematics and local-structure effects cannot be definitively excluded, this result motivates the exploration of alternative physical interpretations beyond the minimal $\Lambda$CDM framework. We investigate whether Scalar--Tensor--Vector Gravity (STVG-MOG) can provide a consistent explanation for an enhanced large-scale anisotropic dipole without violating existing constraints from early-universe cosmology, the cosmic microwave background (CMB) dipole, galaxy dynamics, weak lensing, or the observed late-time matter power spectrum. The radio number-count dipole probes ultra-large-scale, anisotropic structure and coherent gravitational response, rather than virialized dynamics or linear growth alone. In STVG-MOG, a scale- and time-dependent effective gravitational coupling preserves standard cosmological evolution at early times and on small to intermediate scales, while amplifying gravitational response on gigaparsec scales. This scale-selective enhancement can increase the large-scale structure contribution to the radio dipole without overproducing power on smaller scales. If the observed dipole excess reflects a physical cosmological signal rather than residual systematics, STVG-MOG offers a viable and testable alternative interpretation. It is demonstrated that the radio dipole anomaly provides a novel probe of gravitational physics on the largest observable scales.