Resolving Hubble Tension with Quintom Dark Energy Model

Abstract

Recent low-redshift observations give value of the present-time Hubble parameter H0 74~km s-1Mpc-1, roughly 10\% higher than the predicted value H0=67.4~km s-1Mpc-1 from Planck's observations of the Cosmic Microwave Background radiation~(CMB) and the model. Phenomenologically, we show that by adding an extra component X with negative density in the Friedmann equation, it can relieve the Hubble tension without changing the Planck's constraint on the matter and dark energy densities. For the extra negative density to be sufficiently small, its equation-of-state parameter must satisfy 1/3≤ wX≤1. We propose a quintom model of two scalar fields that realizes this condition and potentially alleviate the Hubble tension. One scalar field acts as a quintessence while another "phantom" scalar conformally couples to matter in such a way that viable cosmological scenario can be achieved. The model depends only on two parameters, λφ and δ which represent rolling tendency of the self-interacting potential of the quintessence and the strength of conformal phantom-matter coupling respectively. The toy quintom model with H0=73.4~km s-1Mpc-1~(Quintom I) gives good Supernovae-Ia luminosity fits, decent r BAO fit, but slightly small acoustic multipole A=285.54. Full parameter scan reveals that quintom model provide better model than the model in certain region of the parameter space, 0.02<δ<0.10, m(0)<0.31, while significantly relieving Hubble tension even though not completely resolving it. A benchmark quintom model, Quintom II, is presented as an example.