Abstract
The Palatini $f(|\hat{\Omega}|)$ gravity is a generalized theory of the Eddington-inspired Born-Infeld gravity, where $\Omega_{~N}^{K}\equiv\delta_{~N}^{K}+bg^{KL}R_{LN}(\Gamma)$ is an auxiliary tensor constructed with the spacetime metric $g$ and independent connection $\Gamma$. In this paper, we study $f(|\hat{\Omega}|)$ theory with $f(|\hat{\Omega}|)=|\hat{\Omega}|^{\frac{1}{2}+n}$ in the thick brane scenario and give some constraints on the brane model. We finally found an analytic solution of the thick brane generated by a single scalar field. The behavior of the negative energy density denotes the localization of the thick brane at the origin of the extra dimension. In our braneworld, the warp factor is divergent at the boundary of the extra dimension while the brane system is asymptotically anti$-$de Sitter. It is shown that the tensor perturbation of the brane is stable and the massless graviton is localized on the thick brane. Therefore, the effective Einstein-Hilbert action on the brane can be rebuilt in the low-energy approximation. According to the recent test of the gravitational inverse-square law, we give some constraints on the $f(|\hat{\Omega}|)$ brane.
Highlights
As the most successful gravitational theory, general relativity (GR) is able to explain the gravitational phenomena in the scale ranging from submillimeter to Solar System scales [1], e.g., the deflection of light [2], the precession of Mercury’s perihelion, and so on
The Palatini fðjΩjÞ gravity is a generalized theory of the Eddington-inspired Born-Infeld gravity, where ΩKN ≡ δKN þ bgKLRLNðΓÞ is an auxiliary tensor constructed with the spacetime metric g and independent connection Γ
D-dimensional Newtonian gravitational constant, b is a free parameter in this theory, λ is a parameter related to the cosmological constant, gMN is the spacetime metric, RMNðΓÞ is the symmetric part of the Ricci tensor formed from the independent connection ΓPMN, and SmðgMN; φÞ is CONSTRAINTS ON GENERALIZED EDDINGTON-INSPIRED
Summary
As the most successful gravitational theory, general relativity (GR) is able to explain the gravitational phenomena in the scale ranging from submillimeter to Solar System scales [1], e.g., the deflection of light [2], the precession of Mercury’s perihelion, and so on. This Ωrepresentation of EIBI gravity shows a clear structure of EIBI gravity and one could construct its functional extensions Since, from this point of view, the original theory could be regarded as a particular case of this extended gravity, a natural question comes out, that is, whether the nonsingular solution of the early Universe in EIBI gravity results from the particular form of the action. Inspired by the recent interesting research papers on EIBI branes [38,39,40,41,42,43,44], we aim to give some constraints on the parameters in this particular functional extension of EIBI gravity from its thick brane scenario It could be feasible since, from the point of view of high-dimensional theories, each low-dimensional gravity could be recovered by a mathematical technique called dimensional reduction.
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