A New 5σ Tension at Characteristic Redshift from DESI-DR1 BAO and DES-SN5YR Observations
Abstract
We perform a model-independent reconstruction of the angular diameter distance (DA) using the Multi-Task Gaussian Process (MTGP) framework with DESI-DR1 BAO and DES-SN5YR datasets. We calibrate the comoving sound horizon at the baryon drag epoch rd to the Planck best-fit value, ensuring consistency with early-universe physics. With the reconstructed DA at two key redshifts, z 1.63 (where DA =0) and at z 0.512 (where DA = DA), we derive the expansion rate of the Universe H(z) at these redshifts. Our findings reveal that at z 1.63, the H(z) is fully consistent with the Planck-2018 prediction, confirming no new physics at that redshift. However, at z 0.512, the derived H(z) shows a more than 5σ discrepancy with the Planck-2018 prediction, suggesting a possible breakdown of the model as constrained by Planck-2018 at this lower redshift. This emerging 5σ tension at z 0.512, distinct from the existing ``Hubble Tension'', may signal the first strong evidence for new physics at low redshifts.
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