Symmetric Teleparallel Horndeski Gravity
Abstract
Horndeski gravity is the most general scalar-tensor theory with one scalar field leading to second-order Euler-Lagrange field equations for the metric and scalar field, and it is based on Riemannian geometry. In this paper, we formulate an analogue version of Horndeski gravity in a symmetric teleparallel geometry which assumes that both the curvature (general) and torsion are vanishing and gravity is only related to nonmetricity. Our setup requires that the Euler-Lagrange equations for not only metric and scalar field but also connection should be at most second order. We find that the theory can be always recast as a sum of the Riemannian Horndeski theory and new terms that are purely teleparallel. Due to the nature of nonmetricity, there are many more possible ways of constructing second-order theories of gravity. In this regard, up to some assumptions, we find the most general -essence extension of Symmetric Teleparallel Horndeski gravity. We also formulate a novel theory containing higher-order derivatives acting on nonmetricity while still respecting the second-order conditions, which can be recast as an extension of Kinetic Gravity Braiding. We finish our study by presenting the FLRW cosmological equations for our model.
Cite
@article{arxiv.2212.08005,
title = {Symmetric Teleparallel Horndeski Gravity},
author = {Sebastian Bahamonde and Georg Trenkler and Leonardo G. Trombetta and Masahide Yamaguchi},
journal= {arXiv preprint arXiv:2212.08005},
year = {2023}
}
Comments
35 pages. Matches published version in PRD