Constraining viscous fluid models in f(Q) gravity with data

Abstract

We investigate the impact of bulk viscosity on the accelerating expansion and large-scale structure formation of a Universe in which the underlying gravitational interaction is described by f(Q) gravity. Various paradigmatic choices of the f(Q) gravity theory, including power-law, exponential, and logarithmic models, are considered. To test the cosmological viability of these f(Q) gravity models, we use the Baryon Acoustic Oscillations (BAO) measurements from the Dark Energy Spectroscopic Instrument (DESI) Survey, cosmic chronometers (CC) from Hubble measurements, the SNIa distance moduli measurements from the PantheonP + SH0ES, growth rate (f-data), and redshift-space distortions (fσ8) datasets, the latter two once the linear cosmological perturbations, growth rate f(z), and redshift-space distortion fσ8(z) are studied. Thus, we perform the combined analyses for: PantheonP + SH0ES, PantheonP + SH0ES + f, and PantheonP + SH0ES + fσ8. We compute the best-fit values m, H0\,(km/s/Mpc), rd, Mabs, γ, σ8, n, p and including the bulk viscosity coefficient ζ. Through a detailed statistical analysis, based on the Akaike Information Criterion (AIC) and Bayesian / Schwartz Information Criterion (BIC), a statistical comparison of the f(Q) gravity models with is made. Among the three f(Q) models, only the non-viscous f(Q) power-law model yields robust parameter estimates and substantial observational support without any outright rejections. In contrast, both exponential and logarithmic f(Q) models (with or without bulk viscosity) are rejected by multiple model selection criteria.