Metastable Cosmological Constant and Gravitational Bubbles: Ultra-Late-Time Transitions in Modified Gravity

Abstract

The observed cosmological constant may originate as the minimum value Umin of a scalar field potential, where the scalar field is frozen due to a large mass. If this vacuum is metastable, it may decay to a true vacuum either at present or in the future. Assuming its decay rate is comparable to the Hubble expansion rate H0, we estimate the scale of true vacuum bubbles and analyze their evolution. We find that their initial formation scale is sub-millimeter and their tension causes rapid collapse if m 1.7 · 10-3\, eV. For smaller masses, the bubbles expand at the speed of light. We extend our analysis to scalar-tensor theories with non-minimal coupling, finding that the nucleation scale of gravitational constant bubbles remains consistent with the sub-millimeter regime of General Relativity. The critical mass scale remains around 10-3\,eV. A theoretical estimate at redshift zobs 0.01 suggests an observable bubble radius of 50 Mpc, implying a gravitational transition triggered 300 Myr ago, with a present-day size approaching 100 Mpc. Additionally, we explore mass ranges (m < 10-3\,eV) and non-minimal coupling ranges (10-8\,eV2-n - 10-1\,eV2-n) that lead to a variation G/GN within the 1\%-7\% range. We assume non-minimal coupling of the form F(φ)=1/ - φn, with =8π GN and 2 ≤ n ≤ 9. Finally, we review various local physics or/and transition based proposed solutions to the Hubble tension, including ultra-late-time transitional models (z 0.01), screened fifth-force mechanisms, and the sCDM model, which features a transition at z 2. We discuss observational hints supporting these scenarios and the theoretical challenges they face.

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