Luminal propagation of gravitational waves in scalar-tensor theories: The case for torsion

José Barrientos; Fabrizio Cordonier-Tello; Cristóbal Corral; Fernando Izaurieta; Perla Medina; Eduardo Rodríguez; Omar Valdivia

doi:10.1103/PhysRevD.100.124039

Luminal propagation of gravitational waves in scalar-tensor theories: The case for torsion

José Barrientos, Fabrizio Cordonier-Tello, Cristóbal Corral, Fernando Izaurieta, Perla Medina, Eduardo Rodríguez, Omar Valdivia

Research output: Contribution to journal › Article › peer-review

16 Scopus citations

Abstract

Scalar-tensor gravity theories with a nonminimal Gauss-Bonnet coupling typically lead to an anomalous propagation speed for gravitational waves, and have therefore been tightly constrained by multimessenger observations such as GW170817/GRB170817A. In this paper we show that this is not a general feature of scalar-tensor theories, but rather a consequence of assuming that spacetime torsion vanishes identically. At least for the case of a nonminimal Gauss-Bonnet coupling, removing the torsionless condition restores the canonical dispersion relation and therefore the correct propagation speed for gravitational waves. To achieve this result we develop a new approach, based on the first-order formulation of gravity, to deal with perturbations on these Riemann-Cartan geometries.

Original language	English
Article number	124039
Journal	Physical Review D
Volume	100
Issue number	12
DOIs	https://doi.org/10.1103/PhysRevD.100.124039
State	Published - 16 Dec 2019
Externally published	Yes

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abstract = "Scalar-tensor gravity theories with a nonminimal Gauss-Bonnet coupling typically lead to an anomalous propagation speed for gravitational waves, and have therefore been tightly constrained by multimessenger observations such as GW170817/GRB170817A. In this paper we show that this is not a general feature of scalar-tensor theories, but rather a consequence of assuming that spacetime torsion vanishes identically. At least for the case of a nonminimal Gauss-Bonnet coupling, removing the torsionless condition restores the canonical dispersion relation and therefore the correct propagation speed for gravitational waves. To achieve this result we develop a new approach, based on the first-order formulation of gravity, to deal with perturbations on these Riemann-Cartan geometries.",

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AU - Barrientos, José

AU - Cordonier-Tello, Fabrizio

AU - Corral, Cristóbal

AU - Izaurieta, Fernando

AU - Medina, Perla

AU - Rodríguez, Eduardo

AU - Valdivia, Omar

PY - 2019/12/16

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N2 - Scalar-tensor gravity theories with a nonminimal Gauss-Bonnet coupling typically lead to an anomalous propagation speed for gravitational waves, and have therefore been tightly constrained by multimessenger observations such as GW170817/GRB170817A. In this paper we show that this is not a general feature of scalar-tensor theories, but rather a consequence of assuming that spacetime torsion vanishes identically. At least for the case of a nonminimal Gauss-Bonnet coupling, removing the torsionless condition restores the canonical dispersion relation and therefore the correct propagation speed for gravitational waves. To achieve this result we develop a new approach, based on the first-order formulation of gravity, to deal with perturbations on these Riemann-Cartan geometries.

AB - Scalar-tensor gravity theories with a nonminimal Gauss-Bonnet coupling typically lead to an anomalous propagation speed for gravitational waves, and have therefore been tightly constrained by multimessenger observations such as GW170817/GRB170817A. In this paper we show that this is not a general feature of scalar-tensor theories, but rather a consequence of assuming that spacetime torsion vanishes identically. At least for the case of a nonminimal Gauss-Bonnet coupling, removing the torsionless condition restores the canonical dispersion relation and therefore the correct propagation speed for gravitational waves. To achieve this result we develop a new approach, based on the first-order formulation of gravity, to deal with perturbations on these Riemann-Cartan geometries.

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Luminal propagation of gravitational waves in scalar-tensor theories: The case for torsion

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