Gravitational waves in massive Horndeski theory with a cosmological constant

We study gravitational waves in a de-Sitter background in linearized Horndeski theory. This background can be obtained in different ways in this theory. We first consider an arbitrary potential to implement an effective cosmological constant. The scalar field has long range whereas its potential can induce a mass term, rendering its range to short distances. A second effect of the potential is the possibility to induce a background curvature or an effective cosmological constant via the minimum of the potential. The latter is usually ignored in the literature to have an asymptotically flat background for the gravitational waves. In order to fill this gap, we consider the effects of the scalar potential in the framework of gravitational waves in the theories having such scalar couplings, and compare its effects with other approaches such as the presence of a vacuum energy density filling the spacetime or a linear potential which leads to an effective cosmological constant but now with a massless scalar field. We discuss properties of the gravitational waves, their propagation and interaction with the medium in which they propagate. The minimum of the scalar potential term mimics a cosmological constant and leads to separate redshifts in the effective frequency and wave number, which also discriminates the tensorial and massive scalar waves. We see that, depending on the implementation to have a cosmological constant, the propagation speeds and polarization properties of scalar modes of these waves is different, as summarized in the paper.