Most general fourth-order theory of gravity at low energy

Stabile, A.

doi:10.1103/physrevd.82.124026

Cited by 39 publications

(138 citation statements)

References 33 publications

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“…In order to deal with standard self-gravitating systems, any theory of gravity has to be developed to its Newtonian or post-Newtonian limit depending on the order of approximation of the theory in terms of power of c −2 , where c is the speed of light [49,60]. As we said above a R 2 -theory gives rise to Yukawa-like corrections in the Newtonian potential [61].…”

Section: Extended Gravity and Conformal Transformationsmentioning

confidence: 99%

The dark matter problem from f(R) gravity viewpoint

2012

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An alternative view to the dark matter puzzle is represented by Extended Theories of Gravity. The approach consists in addressing issues like dark components from the point of view of gravitational field instead of requiring new material ingredients that, up to now, have not been detected at fundamental level. In this review paper, by extending the Hilbert‐Einstein action of gravitational field to more general actions (e.g. f(R) gravity), it is shown that several gravitating structures like stars, spiral galaxies, elliptical galaxies and clusters of galaxies can be self‐consistently described without asking for dark matter. It is also shown that standard General Relativity tests and Equivalence Principle constraints can be evaded at Solar System scales.

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Section: Extended Gravity and Conformal Transformationsmentioning

confidence: 99%

The dark matter problem from f(R) gravity viewpoint

2012

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“…Both requirements are fulfilled by General Relativity and then they can be considered two possible paradigms to confront a given theory, at least in the weak field limit, with the General Relativity itself. The Newtonian limit of f (R)-gravity and f (R, R αβ R αβ , R αβγ δ R αβγ δ )-gravity can be investigated always remaining in the Jordan frame (Capozziello et al 2007Stabile 2010aStabile , 2010b while a preliminary study of the post-Minkowskian limit for the f (R) gravity is provided in Capozziello et al (2010b). Here we want to derive the post-Minkowskian limit of f (R, R αβ R αβ , R αβγ δ R αβγ δ ) gravity, that is for generic fourth-order theory of gravity, with the aim to investigate the gravitational radiation.…”

Section: The Post Minkowskian Limitmentioning

confidence: 99%

Gravitational waves in fourth order gravity

Capozziello

Stabile

2015

Astrophys Space Sci

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In the post-Minkowskian limit approximation, we study gravitational wave solutions for general fourthorder theories of gravity. Specifically, we consider a Lagrangian with a generic function of curvature invariants f (R, R αβ R αβ , R αβγ δ R αβγ δ ). It is well known that when dealing with General Relativity such an approach provides massless spin-two waves as propagating degree of freedom of the gravitational field while this theory implies other additional propagating modes in the gravity spectra. We show that, in general, fourth order gravity, besides the standard massless graviton is characterized by two further massive modes with a finite-distance interaction. We find out the most general gravitational wave solutions in terms of Green functions in vacuum and in presence of matter sources. If an electromagnetic source is chosen, only the modes induced by R αβ R αβ are present, otherwise, for any f (R) gravity model, we have the complete analogy with tensor modes of General Relativity. Polarizations and helicity states are classified in the hypothesis of plane wave. B S. Capozziello capozziello@na.infn.it A. Stabile

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“…In order to perform our approximation we have to perturb Eqs. (2), (3) and (4) in a Minkowski background η µν [45,71]. This approximation is sometimes also referred to as an expansion in inverse powers of the speed of light.…”

Section: The Scalar Tensor Fourth Order Gravitymentioning

confidence: 99%

“…while all other possible contributions in f are negligible [45,72,73]. By introducing the quantities…”

Section: The Scalar Tensor Fourth Order Gravitymentioning

confidence: 99%

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Casimir effect in extended theories of gravity

Lambiase

Stabile

2017

Phys. Rev. D

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We study the Casimir vacuum energy density and the Casimir pressure for a massless scalar field confined between two nearby parallel plates in a slightly curved, static spacetime background, employing the weak field approximation in the framework of Extended Theories of Gravity (ETG). Following a perturbative approach upto second order, we find the gravity correction in the ETG to Casimir vacuum energy density and pressure. The corrections to the vacuum energy density in presence of curved spacetime in the framework of General Relativity (GR) are small and today they are still undetected with the current technology. However, future sensitivity improvement in gravitational interferometer experiments will give an useful tool to detect such effect induced by gravity. For these reason we retain interesting from a theoretical point of view generalize the outcomes of GR in the context of ETG. Finally, we find the general relation to constraining the free parameters of the ETG.

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Most general fourth-order theory of gravity at low energy

Cited by 39 publications

References 33 publications

The dark matter problem from f(R) gravity viewpoint

The dark matter problem from f(R) gravity viewpoint

Gravitational waves in fourth order gravity

Casimir effect in extended theories of gravity

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