Linear Higher-Order Maxwell-Einstein-Scalar Theories

Abstract

In the context of the Higher-Order Maxwell-Einstein-Scalar (HOMES) theories, which are invariant under spacetime diffeomorphisms and U(1) gauge symmetry, we study two broad subclasses: the first is up to linear in Rμαβ, ∇μ∇φ, ∇Fμ and up to quadratic in the vector field strength tensor Fμ; the second is up to linear in ∇μ∇φ, contains no second derivatives of vector field and metric, but allows for arbitrary functions/powers of Fμ. Under these assumptions, we systematically derive the most general form of the action that leads to second-order (or lower) equations of motion. We prove that, among 41 possible terms in the first subclass, only four independent higher-derivative terms are allowed: the kinetic gravity braiding term G3(φ,X)φ in the scalar sector with X = -∇μφ ∇μφ / 2; the Horndeski non-minimal coupling term w0(φ)Rβ δ α γFα β Fγ δ in the vector field sector, where Fμ is the Hodge dual of Fμ; and two interaction terms between the scalar and vector field sectors: [w1(φ,X) gσ + w2(φ,X) ∇φ ∇σφ] ∇β∇αφ \, Fα Fβσ. For the second subclass, which admits 11 possible terms, three of these four, excluding the Horndeski non-minimal coupling term proportional to w0(φ), are allowed. These independent terms serve as the building blocks of each subclass of HOMES. Remarkably, there is no higher-derivative parity-violating term in either subclass. Finally, we propose a new generalization of higher-derivative interaction terms for the case of a charged complex scalar field.