Signatures of graviton masses on the CMB

Brax, Philippe; Céspedes, Sebastián; Davis, Anne-Christine

doi:10.1088/1475-7516/2018/03/008

Cited by 8 publications

(7 citation statements)

References 41 publications

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“…We will focus on constraints from late time GW sources. A modified dispersion relation for primordial GWs could be tested with the B-mode polarization of the CMB, as it has been studied for the case of the speed c g [308][309][310], and the mass m g [311][312][313].…”

Section: Gravitational Wave Speedmentioning

confidence: 99%

Dark Energy in Light of Multi-Messenger Gravitational-Wave Astronomy

Ezquiaga

Zumalacárregui

2018

Front. Astron. Space Sci.

209

202

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Gravitational waves (GWs) provide a new tool to probe the nature of dark energy (DE) and the fundamental properties of gravity. We review the different ways in which GWs can be used to test gravity and models for late-time cosmic acceleration. Lagrangian-based gravitational theories beyond general relativity (GR) are classified into those breaking fundamental assumptions, containing additional fields and massive graviton(s). In addition to Lagrangian based theories we present the effective theory of DE and the µ-Σ parametrization as general descriptions of cosmological gravity. Multi-messenger GW detections can be used to measure the cosmological expansion (standard sirens), providing an independent test of the DE equation of state and measuring the Hubble parameter. Several key tests of gravity involve the cosmological propagation of GWs, including anomalous GW speed, massive graviton excitations, Lorentz violating dispersion relation, modified GW luminosity distance and additional polarizations, which may also induce GW oscillations. We summarize present constraints and their impact on DE models, including those arising from the binary neutron star merger GW170817. Upgrades of LIGO-Virgo detectors to design sensitivity and the next generation facilities such as LISA or Einstein Telescope will significantly improve these constraints in the next two decades.

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Section: Gravitational Wave Speedmentioning

confidence: 99%

Dark Energy in Light of Multi-Messenger Gravitational-Wave Astronomy

Ezquiaga

Zumalacárregui

2018

Front. Astron. Space Sci.

209

202

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“…Modified gravity theories provide plausible possibilities, which are worth pursuing and could give a better understanding of observations. In modified gravity theories, the evolution equations of gravitational waves are presented in nonstandard ways [1][2][3][4][5][6][7][8][9][10][11][12][13]. The friction term is a fundamental issue in the propagation of gravitational waves.…”

Section: Introductionmentioning

confidence: 99%

Measuring the Modified Gravitational Wave Propagation beyond General Relativity from CMB Observations

2022

Universe

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In modified gravity theories, gravitational wave propagations are presented in nonstandard ways. We consider a friction term different from GR and constrain the modified gravitational waves propagation from observations. The modified gravitational waves produce anisotropies and polarization, which generate measurable tensor power spectra. We explore the impact of the friction term on the power spectrum of B-modes and the impact on the constraints on the other parameters (e.g., r or At) when ν0 is allowed to vary in the Monte Carlo analyses from Planck+BK18 datasets. If we assume the result of the scalar perturbations is unchanged, the inflation consistency relation alters with the friction term. In the ΛCDM+r+ν0 model, the tensor-to-scalar ratio and the amplitude of the tensor spectrum are obviously influenced.

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“…This doubly coupled theory has been shown to provide viable and interesting cosmological solutions at the background level [35,73], with linear perturbations that are stable at least around specific cosmological backgrounds [80] (see also Refs. [69,[76][77][78]). In particular, in contrast to the singly coupled theory, this double coupling admits combinations of proportional metrics at the background level, and interestingly, the effective metric always corresponds to the massless fluctuations around such backgrounds, i.e.…”

Section: Introductionmentioning

confidence: 99%

Neutron star merger GW170817 strongly constrains doubly coupled bigravity

et al. 2018

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We study the implications of the recent detection of gravitational waves emitted by a pair of merging neutron stars and their electromagnetic counterpart, events GW170817 and GRB170817A, on the viability of the doubly coupled bimetric models of cosmic evolution, where the two metrics couple directly to matter through a composite, effective metric. We demonstrate that the bounds on the speed of gravitational waves place strong constraints on the doubly coupled models, forcing either the two metrics to be proportional at the background level or the models to become singly coupled. Proportional backgrounds are particularly interesting as they provide stable cosmological solutions with phenomenologies equivalent to that of ΛCDM at the background level as well as for linear perturbations, while nonlinearities are expected to show deviations from the standard model.

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Signatures of graviton masses on the CMB

Cited by 8 publications

References 41 publications

Dark Energy in Light of Multi-Messenger Gravitational-Wave Astronomy

Dark Energy in Light of Multi-Messenger Gravitational-Wave Astronomy

Measuring the Modified Gravitational Wave Propagation beyond General Relativity from CMB Observations

Neutron star merger GW170817 strongly constrains doubly coupled bigravity

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