Hubble Tension as an Effect of Horizon Entanglement Nonequilibrium

Abstract

We propose an infrared mechanism for alleviating the Hubble constant tension, based on a small departure from entanglement equilibrium at the cosmological apparent horizon. If the horizon entanglement entropy falls slightly below the Bekenstein-Hawking value, we parametrize the shortfall by a fractional deficit δ(a) evolving with the FLRW scale factor a. The associated equipartition deficit at the Gibbons-Hawking temperature then sources a smooth, homogeneous component whose density scales as H2/G, with a dimensionless coefficient ce2(a) of order unity times δ(a). Because this component tracks H2, it is negligible at early times but can activate at redshifts z 1, raising the late time expansion rate by a few percent without affecting recombination or the sound horizon. We present a minimal three parameter activation model for ce2(a) and derive its impact on the background expansion, effective equation of state, and linear growth for a smooth entanglement sector. The framework predicts a small boost in H(z), a mild suppression of fσ8(z), and a corresponding modification of the low-z distance-redshift relation. We test these predictions against current low-redshift data sets, including SN~Ia distance moduli, baryon acoustic oscillation distance measurements, cosmic chronometer H(z) data, and redshift space distortion constraints, and discuss whether the H0 tension can be consistently interpreted as a late-time, horizon-scale information deficit rather than an early universe modification.