Revisiting Varying Speed of Light in Cosmology: Insights from the Friedmann-Lema\^itre-Robertson-Walker Metric

TL;DR

This paper reinterprets the varying speed of light in cosmology as a gauge choice in general relativity, showing it is not a physical variation but a coordinate-dependent effect, which impacts understanding of cosmic expansion and observational tensions.

Contribution

It demonstrates that the varying speed of light in cosmology is a gauge artifact rather than a physical field, providing a new perspective on cosmological models and the Hubble tension.

Findings

VSL is a gauge choice, not a physical variation.

$ ilde c$ imposes a constraint on the scale factor $a(t)$.

Reinterprets cosmological time and observational tensions within a gauge framework.

Abstract

In the Friedmann-Lema\^itre-Robertson-Walker metric, a varying speed of light (VSL) reflects a change in the clock rate across hypersurfaces, described by the lapse function. This variation is not a dynamical field evolution but a consequence of coordinate choice, as the cosmic time coincides with the proper time of comoving observers due to the Weyl postulate. From an action principle including $\tilde c$, we derive that $\tilde c$ does not have its dynamics but imposes a constraint on the scale factor $a(t)$, indicating that it is not an independent degree of freedom. This insight reframes the VSL concept as a manifestation of gauge freedom in general relativity, wherein physical laws remain invariant under smooth coordinate transformations. Here, gauge refers to the freedom of choosing the temporal coordinate (\textit{e.g.}, setting the lapse $N(t) \neq 1$), which determines how the speed of light appears in the cosmological equations. Recognizing $\tilde c$ as a coordinate-dependent quantity offers a new interpretation of cosmological time and observational tensions, such as the Hubble tension, without invoking new physical fields. This redefinition opens a novel theoretical pathway in interpreting cosmic expansion within a consistent relativistic framework.