The Impact of m0 Prior Bias on Cosmological Parameter Estimation: Reconciling DESI DR2 BAO and Pantheon+ SNe Data Combination Results

Abstract

Recent cosmological parameter analyses combining DESI DR2 Baryon Acoustic Oscillation (BAO) data with external probes, such as Pantheon+ Supernovae (SNe) observations, have reported deviations of the dark energy equation-of-state parameters (, ) from the standard model predictions (=-1, =0). A notable aspect of these results is the role of prior information from SNe, which is known to exhibit tension with BAO-only constraints. In this study, we rigorously investigate this effect through a statistical analysis using 1000 mock DESI DR2 BAO data realizations. We demonstrate that the strong degeneracy between , , and causes significant biases in the estimated dark energy parameters when the prior mean deviates from its true underlying value. Specifically, applying an prior mean of 0.33 (consistent with some SNe-only constraints) to mock data, assuming a true universe (=0.30, =-1, =0), yields biased estimates such as ≈ -0.82 0.06 and ≈ -0.82 0.4. This systematic shift, driven by the prior, moves the estimated parameters towards the non- region, offering a qualitative resemblance to outcomes reported in current combined DESI DR2 BAO + Pantheon+ SNe analyses (e.g., = -0.888+0.055-0.064, = -0.17 0.46). Our findings suggest that these observed non- parameters may largely arise from statistical biases due to prior tensions between datasets. This study proposes a potential resolution to current cosmological tensions without necessarily invoking new physics.