Horndeski theories confront the Gravity Probe B experiment

Mukherjee, Sajal; Chakraborty, Sumanta

doi:10.1103/physrevd.97.124007

Cited by 42 publications

(30 citation statements)

References 128 publications

(150 reference statements)

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“…Before concluding this section, let us briefly mention that even though these results are derived in the context of black holes, they remain equally applicable in the context of neutron stars as well, as long as the Weyl stress in the exterior region of the neutron star continues to be given by Eq. (21). In that case, Eq.…”

Section: Tidal Love Numbers Of Braneworld Black Holesmentioning

confidence: 95%

“…Thus with GW astronomy established on a firm footing, we can now turn our attention to answer some of the more fundamental questions of nature. These include: (a) subtle relations regarding black hole physics (e.g., no-hair theorem, area increase theorem, existence of black hole horizons themselves) [8][9][10][11][12][13]; (b) evidence of theories beyond general relativity, in particular, presence of higher curvature terms in the Einstein-Hilbert action, theories involving specific curvature scalar coupling, known as Horndeski theories are of significant interest among others [14][15][16][17][18][19][20][21][22][23][24][25] and finally (c) fundamental structure of the spacetime itself [26][27][28][29][30][31][32]. An interesting line of thought in understanding the fundamental structure of spacetime happens to be the question of presence (or absence) of extra spatial dimensions to our usual four-dimensional spacetime.…”

Section: Introductionmentioning

confidence: 99%

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Tidal Love numbers of black holes and neutron stars in the presence of higher dimensions: Implications of GW170817

et al. 2019

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We calculate the tidal Love numbers of black holes and neutron stars in the presence of higher dimensions. The perturbation equations around an arbitrary static and spherically symmetric metric for the even parity modes are presented in the context of an effective four-dimensional theory on the brane. This subsequently leads to the sought expression for the tidal Love number for black holes in the presence of extra spatial dimensions. Surprisingly, these numbers are non-zero and, more importantly, negative. We extend our method to determine the tidal Love number of neutron stars in a spacetime inheriting extra dimensions and show that, in the context of effective gravitational theory on the brane, they are smaller than in general relativity. Finally we have explicitly demonstrated that earlier constraints on the parameters inherited from higher dimensions are consistent with the bound on the tidal deformability parameter from the GW170817 event as well.

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Section: Tidal Love Numbers Of Braneworld Black Holesmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Tidal Love numbers of black holes and neutron stars in the presence of higher dimensions: Implications of GW170817

et al. 2019

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“…Following such implications in mind, there have been attempts to study circular timelike geodesics in presence of NUT parameter [14][15][16] 1 as well as motion of charged particles in this spacetime [17]. Various weak field tests, e.g., perihelion precession, Lense-Thirring effect has also been discussed [18][19][20] (for a taste of these weak field tests in theories beyond general relativity, see [21][22][23][24][25]). We would like to emphasize that most of these studies on the geodesic motion crucially hinges on the equatorial plane, however there can also be interesting phenomenon when off-the-equatorial plane motion is considered.…”

Section: Introductionmentioning

confidence: 99%

On some novel features of the Kerr–Newman-NUT spacetime

2019

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In this work we have presented a special class of Kerr-Newman-NUT black hole, having its horizon located precisely at r = 2M , for Q 2 = l 2 − a 2 , where M , l, a and Q are respectively mass, NUT, rotation and electric charge parameters of the black hole. Clearly this choice radically alters the causal structure as there exists no Cauchy horizon indicating spacelike nature of the singularity when it exists. On the other hand, there is no curvature singularity for l 2 > a 2 , however it may have conical singularities. Furthermore there is no upper bound on specific rotation parameter a/M , which could exceed unity without risking destruction of the horizon. To bring out various discerning features of this special member of the Kerr-Newman-NUT family, we study timelike and null geodesics in the equatorial as well as off the equatorial plane, energy extraction through super-radiance and Penrose process, thermodynamical properties and also the quasi-periodic oscillations. It turns out that the black hole under study radiates less energy through the super-radiant modes and Penrose process than the other black holes in this family. * sm13ip029@iiserkol.ac.in

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“…In particular, the detection of GW170817 [1] refuted whole families of theories [2][3][4]. Together with other experimental results [5], this amounts to a renewed challenge on alternative gravitational theories.…”

Section: Introductionmentioning

confidence: 91%

Linear and second-order geometry perturbations on spacetimes with torsion

2019

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In order to study gravitational waves in any realistic astrophysical scenario, one must consider geometry perturbations up to second order. Here, we present a general technique for studying linear and quadratic perturbations on a spacetime with torsion. Besides the standard metric mode, a "torsionon" perturbation mode appears. This torsional mode will be able to propagate only in a certain kind of theories.

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Horndeski theories confront the Gravity Probe B experiment

Cited by 42 publications

References 128 publications

Tidal Love numbers of black holes and neutron stars in the presence of higher dimensions: Implications of GW170817

Tidal Love numbers of black holes and neutron stars in the presence of higher dimensions: Implications of GW170817

On some novel features of the Kerr–Newman-NUT spacetime

Linear and second-order geometry perturbations on spacetimes with torsion

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