Evolving Dark Energy with w Deviating from -1
arXiv:astro-ph/0503706 · doi:10.1103/PhysRevLett.95.141302
Abstract
Theories of evolving quintessence are constructed that generically lead to deviations from the w = -1 prediction of non-evolving dark energy. The small mass scale that governs evolution, m_Ï\approx 10^{-33} eV, is radiatively stable, and the ``Why Now?'' problem is solved. These results rest crucially on seesaw cosmology: in broad outline, fundamental physics and cosmology can be understood from only two mass scales, the weak scale, v, and the Planck scale, M. Requiring a scale of dark energy Ï_{DE}^{1/4} governed by v^2/M, and a radiatively stable evolution rate m_Ïgiven by v^4/M^3, leads to a distinctive form for the equation of state w(z) that follows from a cosine quintessence potential. An explicit hidden axion model is constructed. Dark energy resides in the potential of the axion field which is generated by a new QCD-like force that gets strong at the scale Î\approx v^2/M \approx Ï_{DE}^{1/4}. The evolution rate is given by a second seesaw that leads to the axion mass, m_Ï\approx Î^2/f, with f \approx M.
4 pages