Suggestions of decreasing dark energy from supernova and BAO data: an update

Abstract

In a previous work 2305.04946, we found that supernova and baryon acoustic oscillation data support the hypothesis that late time cosmic acceleration is caused by the potential energy of a scalar field descending its potential, as suggested by holographically defined models of quantum gravity. In this note, we update our analysis using the Dark Energy Survey 5 year supernova data set (DES-SN5YR) and the baryon acoustic oscillation data from the Dark Energy Spectroscopic Instrument Data Release 2 (DESI DR2). Approximating the scalar potential via a first order Taylor series V ≈ V0 + V1 φ about the present value, and making use of only recent-time data from DES-SN5YR and DESI DR2, we find that the slope parameter is constrained as V1 = 1.49 0.25 in a standard likelihood analysis. This is naively a >5 σ discrepancy with (which has V1 =0), though a more detailed analysis not assuming a Gaussian likelihood distribution suggests 4 σ significance. Based only on the 2 = -13.7 improvement of fit while ignoring parameter space volumes disfavours at a 3 σ significance level. These significance measures are substantially improved from our previous analysis using older data sets. We also reproduce the DESI DR2 parameter constraints based on the same combination of data and find that the is more strongly disfavoured in the context of the linear potential extension (dubbed V0V1) as compared with the w0 wa extension of . A caveat is that for both w0 wa and V0 V1, much of the significance relies on the historical z < 0.1 supernova samples included in the DES-SN5YR data set.