Abstract
We consider the (gauged) Weyl gravity action, quadratic in the scalar curvature ( tilde{R} ) and in the Weyl tensor ( {tilde{C}}_{mu nu rho sigma} ) of the Weyl conformal geometry. In the absence of matter fields, this action has spontaneous breaking in which the Weyl gauge field ωμ becomes massive (mass mω ∼ Planck scale) after “eating” the dilaton in the tilde{R} 2 term, in a Stueckelberg mechanism. As a result, one recovers the Einstein-Hilbert action with a positive cosmological constant and the Proca action for the massive Weyl gauge field ωμ. Below mω this field decouples and Weyl geometry becomes Riemannian. The Einstein-Hilbert action is then just a “low-energy” limit of Weyl quadratic gravity which thus avoids its previous, long-held criticisms. In the presence of matter scalar field ϕ1 (Higgs-like), with couplings allowed by Weyl gauge symmetry, after its spontaneous breaking one obtains in addition, at low scales, a Higgs potential with spontaneous electroweak symmetry breaking. This is induced by the non-minimal coupling {xi}_1{phi}_1^2tilde{R} to Weyl geometry, with Higgs mass ∝ ξ1/ξ0 (ξ0 is the coefficient of the tilde{R} 2 term). In realistic models ξ1 must be classically tuned ξ1 ≪ ξ0. We comment on the quantum stability of this value.
Highlights
JHEP03(2019)049 in the scalar curvature Rof Weyl geometry [9, 10]
We show that the Stueckelberg mechanism is still present, with an additional benefit: the Higgs potential has spontaneous electroweak symmetry breaking
We considered the general action of Weyl gravity in the absence of matter, which is the sum of two terms quadratic in the curvature scalar (R) and in the Weyl tensor (Cμνρσ) of the Weyl conformal geometry, studied its spontaneous breaking
Summary
Let us review some aspects of Weyl geometry needed when discussing Weyl gauge invariance of the action. Leff is uninteresting: derived from (2.8) and invariant under (2.1), it has a remaining “fake” conformal symmetry [52, 53]: its associated current is vanishing This follows the absence of a kinetic term for the Weyl field which allowed its integration.. In the decoupling limit of the massive Weyl gauge field, Weyl geometry “flows” into a Riemannian geometry This may be seen dynamically from the conserved current in (2.18) which for a FRW metric is driving φ0 to a constant value [39] (in this case ∝ M ). It is interesting that Lagrangian (2.8), (2.9) dictated by Weyl geometry (no matter) is so rich in structure, encoding Stueckelberg mechanism, dilaton φ0, Einstein action, Proca action for massive ωμ, a positive cosmological constant and fields kinetic terms and interactions
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