Constraining GREA, an alternative theory accounting for the present cosmic acceleration

Abstract

The origin of the Universe's late-time accelerated expansion remains unknown. The General Relativistic Entropic Acceleration (GREA) theory offers a compelling alternative to , attributing cosmic acceleration to entropy growth associated with cosmic and black hole horizons, without invoking a cosmological constant. We test GREA against the latest DESI DR2 Baryon Acoustic Oscillations (BAO), multiple Type Ia supernova compilations (Union3, Pantheon+, DES-SN5YR), and cosmic microwave background (CMB) distance measurements. While GREA is not nested within , it achieves a comparable goodness-of-fit, highlighting its potential as a theoretically motivated framework that circumvents some of the fine-tuning issues of the standard cosmology. We find that the best-fit model features a transient phantom crossing at z 2, with wa d w(a=1)/da -0.3, in good agreement with observations. However, its present-day value w0 w(z=0) is tightly constrained to be w0-1. Upcoming low-redshift (i.e. z < 1) cosmological probes, from both background and perturbations, will offer promising avenues for further exploring the viability of the GREA theory.