Higher Dimensional Static and Spherically Symmetric Solutions in Extended Gauss–Bonnet Gravity

We study a theory of gravity of the form f ( G ) where G is the Gauss–Bonnet topological invariant without considering the standard Einstein–Hilbert term as common in the literature, in arbitrary ( d + 1 ) dimensions. The approach is motivated by the fact that, in particular conditions, the Ricci curvature scalar can be easily recovered and then a pure f ( G ) gravity can be considered a further generalization of General Relativity like f ( R ) gravity. Searching for Noether symmetries, we specify the functional forms invariant under point transformations in a static and spherically symmetric spacetime and, with the help of these symmetries, we find exact solutions showing that Gauss–Bonnet gravity is significant without assuming the Ricci scalar in the action.

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Exact Spherically Symmetric Solutions in Modified Gauss–Bonnet Gravity from Noether Symmetry Approach

Symmetry ◽

10.3390/sym12010068 ◽

2020 ◽

Vol 12 (1) ◽

pp. 68 ◽

Cited By ~ 6

Author(s):

Sebastian Bahamonde ◽

Konstantinos Dialektopoulos ◽

Ugur Camci

Keyword(s):

Vector Fields ◽

Selection Criterion ◽

Alternative Theories Of Gravity ◽

Spherically Symmetric ◽

Lie Point Symmetries ◽

Noether Symmetries ◽

Symmetry Approach ◽

Point Transformations ◽

Spherically Symmetric Solutions ◽

Theories Of Gravity

It is broadly known that Lie point symmetries and their subcase, Noether symmetries, can be used as a geometric criterion to select alternative theories of gravity. Here, we use Noether symmetries as a selection criterion to distinguish those models of f ( R , G ) theory, with R and G being the Ricci and the Gauss–Bonnet scalars respectively, that are invariant under point transformations in a spherically symmetric background. In total, we find ten different forms of f that present symmetries and calculate their invariant quantities, i.e., Noether vector fields. Furthermore, we use these Noether symmetries to find exact spherically symmetric solutions in some of the models of f ( R , G ) theory.

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Spherically symmetric solutions in dimensionally reduced spacetimes with a higher-dimensional cosmological constant

Physical Review D ◽

10.1103/physrevd.44.1100 ◽

1991 ◽

Vol 44 (4) ◽

pp. 1100-1114 ◽

Cited By ~ 48

Author(s):

David L. Wiltshire

Keyword(s):

Cosmological Constant ◽

Spherically Symmetric ◽

Higher Dimensional ◽

Spherically Symmetric Solutions

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Higher dimensional Penrose inequality in spherically symmetric spacetime

Chinese Journal of Physics ◽

10.1016/j.cjph.2016.05.008 ◽

2016 ◽

Vol 54 (4) ◽

pp. 582-586

Author(s):

Alam H. Hidayat ◽

Fiki T. Akbar ◽

Bobby E. Gunara

Keyword(s):

Spherically Symmetric ◽

Penrose Inequality ◽

Higher Dimensional ◽

Symmetric Spacetime ◽

Spherically Symmetric Spacetime

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Higher-dimensional gravitational collapse of perfect fluid spherically symmetric spacetime in f(R, T) gravity

Modern Physics Letters A ◽

10.1142/s0217732318500657 ◽

2018 ◽

Vol 33 (12) ◽

pp. 1850065 ◽

Cited By ~ 4

Author(s):

Suhail Khan ◽

Muhammad Shoaib Khan ◽

Amjad Ali

Keyword(s):

Perfect Fluid ◽

Outer Region ◽

Energy Tensor ◽

Spherically Symmetric ◽

Field Equations ◽

Higher Dimensional ◽

Stress Energy ◽

Inner Region ◽

Symmetric Spacetime ◽

Spherically Symmetric Spacetime

In this paper, our aim is to study (n + 2)-dimensional collapse of perfect fluid spherically symmetric spacetime in the context of f(R, T) gravity. The matching conditions are acquired by considering a spherically symmetric non-static (n + 2)-dimensional metric in the inner region and Schwarzschild (n + 2)-dimensional metric in the outer region of the star. To solve the field equations for above settings in f(R, T) gravity, we choose the stress–energy tensor trace and the Ricci scalar as constants. It is observed that two physical horizons, namely, cosmological and black hole horizons appear as a consequence of this collapse. A singularity is also formed after the birth of both the horizons. It is also observed that the term f(R0, T0) slows down the collapsing process.

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Exact Spherically Symmetric Solutions in Modified Teleparallel Gravity

Symmetry ◽

10.3390/sym11121462 ◽

2019 ◽

Vol 11 (12) ◽

pp. 1462 ◽

Cited By ~ 7

Author(s):

Sebastian Bahamonde ◽

Ugur Camci

Keyword(s):

Exact Solutions ◽

Modified Gravity ◽

Teleparallel Gravity ◽

Boundary Term ◽

Spherically Symmetric ◽

Noether Symmetries ◽

Noether Theorem ◽

Symmetry Approach ◽

Spherically Symmetric Solutions ◽

Teleparallel Theory

Finding spherically symmetric exact solutions in modified gravity is usually a difficult task. In this paper, we use Noether symmetry approach for a modified teleparallel theory of gravity labeled as f ( T , B ) gravity where T is the scalar torsion and B the boundary term. Using Noether theorem, we were able to find exact spherically symmetric solutions for different forms of the function f ( T , B ) coming from Noether symmetries.

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New spherically symmetric solutions in f (R)-gravity by Noether symmetries

General Relativity and Gravitation ◽

10.1007/s10714-012-1367-y ◽

2012 ◽

Vol 44 (8) ◽

pp. 1881-1891 ◽

Cited By ~ 44

Author(s):

Salvatore Capozziello ◽

Noemi Frusciante ◽

Daniele Vernieri

Keyword(s):

Spherically Symmetric ◽

Noether Symmetries ◽

Spherically Symmetric Solutions

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The two-body problem: an effective-one-body approach

10.1093/oso/9780198786399.003.0056 ◽

2018 ◽

Author(s):

Nathalie Deruelle ◽

Jean-Philippe Uzan

Keyword(s):

Body Problem ◽

Equations Of Motion ◽

Reaction Force ◽

Kerr Black Hole ◽

Radiation Reaction ◽

Spherically Symmetric ◽

Geodesic Motion ◽

Two Body Problem ◽

Symmetric Spacetime ◽

Radiation Reaction Force

This chapter presents the basics of the ‘effective-one-body’ approach to the two-body problem in general relativity. It also shows that the 2PN equations of motion can be mapped. This can be done by means of an appropriate canonical transformation, to a geodesic motion in a static, spherically symmetric spacetime, thus considerably simplifying the dynamics. Then, including the 2.5PN radiation reaction force in the (resummed) equations of motion, this chapter provides the waveform during the inspiral, merger, and ringdown phases of the coalescence of two non-spinning black holes into a final Kerr black hole. The chapter also comments on the current developments of this approach, which is instrumental in building the libraries of waveform templates that are needed to analyze the data collected by the current gravitational wave detectors.

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