Illustrating the consequences of a misuse of σ8 in cosmology

Abstract

The parameter σ8 is the rms mass fluctuations on a scale of R8=8h-1 Mpc and is used to quantify the amplitude of matter fluctuations at linear scales. However, the dependence of R8 on h complicates direct comparisons of σ8 values obtained under different assumptions about H0, since σ8 in such cases characterizes the amount of structure at different physical scales. This issue arises both when comparing σ8 values from fitting analyses of cosmological models with differing H0 posteriors, and when contrasting constraints from galaxy clustering experiments with different priors on H0. As first noted by Ariel G. S\'anchez in PRD 102, 123511 (2020), quantifying the growth tension using σ8 can introduce substantial biases and couple the growth and Hubble tensions in an intricate way. To address these challenges, S\'anchez proposed an alternative parameter, σ12, defined as the rms mass fluctuations at 12 Mpc, which is independent of h. Although S\'anchez's work was published five years ago and other authors have since highlighted the limitations of σ8, much of the cosmological community -- including large collaborations -- continues to rely on this parameter rather than adopting σ12, seemingly due only to historical considerations. In this work, we illustrate the biases introduced by σ8 through some clear examples, aiming to motivate the community to transition from σ8 to σ12. We show that the bias found in models with large values of H0 is more prominent, artificially complicating the search for a model that can efficiently resolve the Hubble tension without exacerbating the growth tension inferred from galaxy clustering measurements. We argue that the worsening of the growth tension in these models is much less pronounced than previously thought or may even be nonexistent.