Conformal symmetry and nonlinear extensions of nonlocal gravity

Cusin, Giulia; Foffa, Stefano; Maggiore, Michele; Mancarella, Michele

doi:10.1103/physrevd.93.083008

Cited by 22 publications

(62 citation statements)

References 83 publications

(195 reference statements)

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“…This is the operator that enters in the conformal anomaly in four dimensions and, from the point of view of conformal invariance, is the natural generalization of the d'Alembertian from two to four dimensions. This model had a viable cosmological evolution [240], although its prediction for the equation of state of DE, w 0 −1.31, already seemed off with respect to the observations, as was indeed confirmed from a MCMC analysis in [23]. In any case, what definitely ruled out the model was the realization that, in the tensor sector, it predicts a speed of GWs different from the speed of light [23].…”

Section: Discussionmentioning

confidence: 70%

Gravity in the infrared and effective nonlocal models

Belgacem

Dirian

Finke

et al. 2020

J. Cosmol. Astropart. Phys.

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We provide a systematic and updated discussion of a research line carried out by our group over the last few years, in which gravity is modified at cosmological distances by the introduction of nonlocal terms, assumed to emerge at an effective level from the infrared behavior of the quantum theory. The requirement of producing a viable cosmology turns out to be very stringent and basically selects a unique model, in which the nonlocal term describes an effective mass for the conformal mode. We discuss how such a specific structure could emerge from a fundamental local theory of gravity, and we perform a detailed comparison of this model with the most recent cosmological datasets, confirming that it fits current data at the same level as ΛCDM.Most notably, the model has striking predictions in the sector of tensor perturbations, leading to a very large effect in the propagation of gravitational wave (GWs) over cosmological distances. At the redshifts relevant for the next generation of GW detectors such as Einstein Telescope, Cosmic Explorer and LISA, this leads to deviations from GR that could be as large as 80%, and could be verified with the detection of just a single coalescing binary with electromagnetic counterpart. This would also have potentially important consequences for the search of the counterpart since, for a given luminosity distance to the source, as inferred through the GW signal, the actual source redshift could be significantly different from that predicted by ΛCDM. At the redshifts relevant for advanced LIGO/Virgo/Kagra the effect is smaller, but still potentially observable over a few years of runs at target sensitivity. arXiv:2001.07619v1 [astro-ph.CO] 21 Jan 2020 4 Conclusions 66 A Difficulties of alternative nonlocal models 68 -1 -2 The Lichnerowicz operator is defined by E µν,ρσ ≡ 1 2, where 2 = η µν ∂µ∂ν is the flat-space d'Alembertian. We use the signature ηµν = (−, +, +, +) and MTW [14] sign conventions. 3 We assume here 3 + 1 spacetime dimensions. See [13] for the corresponding equations in d + 1 spacetime dimensions, with d generic.

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Section: Discussionmentioning

confidence: 70%

Gravity in the infrared and effective nonlocal models

Belgacem

Dirian

Finke

et al. 2020

J. Cosmol. Astropart. Phys.

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“…These are nonlocal gravitational interactions dictating the behaviour of gravitational interactions at large cosmological scales. It can be understood as a heuristic derivation of the non-local action that has been studied extensively in [11,12,14] and is seen to agree with the various cosmological data as good as Λ-CDM. Defining the induced Newton's constant as 9/(32πG) −1 = ξ 1 κ 2 , and pulling out the factor of Planck's mass from the action allows to make comparison with the existing models in [11,12,14].…”

Section: Local To Non-localmentioning

confidence: 90%

“…It is reasonably well understood that a slowly rolling scalar give rise to negative pressure generating dark energy effects, which is the case in quintessence model [3][4][5][6] and k-essence model [7][8][9]. Beside the existence of other possibilities, an interesting proposal involving non-locality has been proposed recently [10][11][12], where it was noticed that a particular kind of non-locality generates late-time accelerated expansion in the Universe fitting the darkenergy data as well as Λ-CDM [13,14]. However, a fundamental local explanation for it is currently lacking.…”

Section: Introductionmentioning

confidence: 99%

“…The scale-invariant higher-derivative induced gravity model coupled with scalars, undergoes symmetry breaking via quantum corrections [18], thereby inducing mass for the scalar leading to its decoupling [19,20]. In a model comprising of more than one scalar, if one of the scalar gets decoupled, a phase of accelerated expansion is achieved at late times arising due to the generation of non-locality following the integration of residual scalars [11,12,14].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Non-Locality and Late-Time Cosmic Acceleration from an Ultraviolet Complete Theory †

Narain

2018

Universe

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A local phenomenological model that reduces to a non-local gravitational theory giving dark energy is proposed. The non-local gravity action is known to fit the data as well as Λ-CDM thereby demanding a more fundamental local treatment. It is seen that the scale-invariant higher-derivative scalar-tensor theory of gravity, which is known to be ultraviolet perturbative renormalizable to all loops and where ghosts become innocuous, generates non-locality at low energies. The local action comprises of two real scalar fields coupled non-minimally with the higher-derivative gravity action. When one of the scalar acquiring the Vacuum Expectation Value (VEV) induces Einstein-Hilbert gravity, generates mass for fields, and gets decoupled from system, it leaves behind a residual theory which in turn leads to a non-local gravity generating dark energy effects.

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“…Perturbations and physical excitations of the equations of motion of action (24) around the de Sitter background are considered in [34] and [35], respectively. As some recent developments in nonlocal modified gravity, see [44,21,25,41,53,68].…”

Section: Discussionmentioning

confidence: 99%

On Nonlocal Modified Gravity and Its Cosmological Solutions

Dimitrijevic

Драгович

Stanković

et al. 2016

Springer Proceedings in Mathematics &Amp; Statistics

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During hundred years of General Relativity (GR), many significant gravitational phenomena have been predicted and discovered. General Relativity is still the best theory of gravity. Nevertheless, some (quantum) theoretical and (astrophysical and cosmological) phenomenological difficulties of modern gravity have been motivation to search more general theory of gravity than GR. As a result, many modifications of GR have been considered. One of promising recent investigations is Nonlocal Modified Gravity. In this article we present a brief review of some nonlocal gravity models with their cosmological solutions, in which nonlocality is expressed by an analytic function of the d'Alembert-Beltrami operator . Some new results are also presented.

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Conformal symmetry and nonlinear extensions of nonlocal gravity

Cited by 22 publications

References 83 publications

Gravity in the infrared and effective nonlocal models

Gravity in the infrared and effective nonlocal models

Non-Locality and Late-Time Cosmic Acceleration from an Ultraviolet Complete Theory †

On Nonlocal Modified Gravity and Its Cosmological Solutions

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