Quantum Vacuum energy as the origin of Gravity

Abstract

We explore the idea that quantum vacuum energy vac is at the origin of Gravity. We formulate a gravitational version of the electromagnetic Casimir effect, and provide an argument for how gravity can arise from vac by showing how Einstein's field equations emerge in the form of Friedmann's equations. This leads to the idea that Newton's constant GN is environmental, namely it depends on the total mass-energy of the Universe M∞ and its size R∞ , with GN = c2 R∞ /2 M∞. This leads to a new interpretation of the Gibbons-Hawking entropy of de Sitter space, and also the Bekenstein-Hawking entropy for black holes, wherein the quantum information bits are quantized massless particles at the horizon with wavelength λ = 2 π R∞. We assume a recently proposed formula for vac mz4/g, where mz is the mass of the lightest particle, and g is a marginally irrelevant coupling. This leads to an effective, induced RG flow for Newton's constant GN as a function of an energy scale, which indicates that GN decreases at higher energies until it reaches a Landau pole at a minimal value of the cosmological scale factor a(t) > a min, thus avoiding the usual geometric singularity at a=0. The solution to the scale factor satisfies an interesting symmetry between the far past and far future due to a(t) = a(-t + 2 t min), where a(t min) = a min. We propose that this energy scale dependent GN can explain the Hubble tension and we thereby constrain the coupling constant g and its renormalization group parameters. For the CDM model we estimate a min ≈ e-1/b where b ≈ 0.02 based on the Hubble tension data.