http://arxiv.org/abs/1908.02534
We investigate infrared dynamics of four-dimensional Einstein gravity in de Sitter space. We set up a general framework to investigate dynamical scaling relations in quantum/classical gravitational theories. The conformal mode dependence of Einstein gravity is renormalized to the extent that general covariance is not manifest. We point out that the introduction of an inflaton is necessary as a counter term. We observe and postulate a duality between quantum effects in Einstein gravity and classical evolutions in inflation/quintessence models. The quantum effective action of Einstein gravity can be constructed as inflation/quintessence models with manifest general covariance. We show that $g=G_N H^2/\pi$: the only dimensionless coupling of $H^2$ (Hubble parameter) and $G_N$ (Newton’s coupling) in Einstein gravity is screened by the infrared logarithmic fluctuations of the conformal mode. We evaluate the one-loop $\beta$ function of $g$ with respect to the cosmic time $\log Ht$ as $\beta(g)=-(1/2)g^2$, i.e., $g$ is asymptotically free toward future. We have identified de Sitter entropy $1/g$ with von Neumann entropy of the conformal zero modes. The former evolves according to the $\beta$ function and Gibbons-Hawking formula. The latter is found to increase by diffusion in the stochastic process at the horizon in a consistent way. Our Universe is located very close to the fixed point $g=0$ with a large entropy. We discuss possible physical implications of our results such as logarithmic decay of dark energy.
H. Kitamoto, Y. Kitazawa and T. Matsubara
Thu, 8 Aug 19
71/78
Comments: 40 pages, 1 figure
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