English

Interacting hypersurfaces and multiple scalar-tensor theories

General Relativity and Quantum Cosmology 2024-11-01 v2 High Energy Physics - Theory

Abstract

We propose a novel method to construct ghost-free multiple scalar-tensor theories. The key idea is to use the geometric quantities of hypersurfaces defined by the scalar fields, rather than the covariant derivatives of scalar fields or spacetime curvature, to build the theory. This approach has proven effective in developing ghost-free scalar-tensor theories in the single-field case. When multiple scalar fields are present, each field specifies a foliation of spacelike hypersurfaces, on which we can define the normal vector, induced metric, extrinsic and intrinsic curvatures, as well as extrinsic (Lie) and intrinsic (spatial) derivatives, respectively. By employing these hypersurface geometric quantities as foundational elements, we construct the Lagrangian for interacting hypersurfaces that describes a multiple scalar-tensor theory. Given that temporal (Lie) and spatial derivatives are separated, it becomes relatively easier to control the order of time derivatives, thus helping to avoid ghost-like or unwanted degrees of freedom. In this work, we use bi-scalar-field theory as an example, focusing on polynomial-type Lagrangians. We construct monomials of hypersurface geometric quantities up to d=3d=3, where dd denotes the number of derivatives in each monomial. Additionally, we present the correspondence between expressions in terms of hypersurface quantities and those in covariant bi-scalar-tensor theory. Through a cosmological perturbation analysis of a simple model, we demonstrate that the theory propagates two tensor and two scalar degrees of freedom at the linear order in perturbations, thereby remaining free from any extra degrees of freedom.

Keywords

Cite

@article{arxiv.2410.12680,
  title  = {Interacting hypersurfaces and multiple scalar-tensor theories},
  author = {Yang Yu and Zheng Chen and Yu-Min Hu and Xian Gao},
  journal= {arXiv preprint arXiv:2410.12680},
  year   = {2024}
}

Comments

28 pages, 1 figure; v2, typos corrected

R2 v1 2026-06-28T19:24:24.790Z