Nonminimal coupling and the cosmological constant problem
Abstract
We consider a universe with a positive effective cosmological constant and a nonminimally coupled scalar field. When the coupling constant is negative, the scalar field exhibits linear growth at asymptotically late times, resulting in a decaying effective cosmological constant. The Hubble rate in the Jordan frame reaches a self-similar solution, , where the principal slow roll parameter depends on , reaching maximally (radiation era scaling) in the limit when . Similar results are found in the Einstein frame (E), with , but now as . Therefore in the presence of a nonminimally coupled scalar de Sitter is not any more an attractor, but instead (when ) the Universe settles in a decelerating phase. Next we show that, when the scalar field decays to matter with at a rate , the scaling changes to that of matter, , and the energy density in the effective cosmological becomes a fixed fraction of the matter energy density, , exhibiting thus an attractor behavior. While this may solve the (old) cosmological constant problem, it does not explain dark energy. Provided one accepts tuning at the level, the vacuum energy of neutrinos can explain the observed dark energy.
Cite
@article{arxiv.1504.00842,
title = {Nonminimal coupling and the cosmological constant problem},
author = {Dražen Glavan and Tomislav Prokopec},
journal= {arXiv preprint arXiv:1504.00842},
year = {2015}
}
Comments
22 pages, 7 figures