Litcius/Paper detail

Generalized Brans-Dicke theories in light of evolving dark energy

Alex Zucca, Levon Pogosian, Alessandra Silvestri, Yuting Wang, Gong‐Bo Zhao

2020Physical review. D/Physical review. D.13 citationsDOIOpen Access PDF

Abstract

The expansion history of the Universe reconstructed from a combination of recent data indicates a preference for a changing dark energy (DE) density. Moreover, the DE density appears to be increasing with cosmic time, with its equation of state being below $\ensuremath{-}1$ on average, and possibly crossing the so-called phantom divide. Scalar-tensor theories, in which the scalar field mediates a force between matter particles, offer a natural framework in which the effective DE equation of state can be less than $\ensuremath{-}1$ and cross the phantom barrier. We consider the generalized Brans-Dicke (GBD) class of scalar-tensor theories and reconstruct their Lagrangian given the effective DE density extracted from recent data. Then, given the reconstructed Lagrangian, we solve for the linear perturbations and investigate the characteristic signatures of these reconstructed GBD in the cosmological observables, such as the cosmic microwave background (CMB) anisotropy, the galaxy number counts, and their cross-correlations. In particular, we demonstrate that the integrated Sachs-Wolfe effect probed by the cross-correlation of CMB with the matter distribution can rule out scalar-tensor theories as the explanation of the observed DE dynamics independently from the laboratory and Solar System fifth force constraints.

Topics & Concepts

PhysicsDark energyCosmic microwave backgroundScalar (mathematics)Dark matterObservableScalar–tensor theoryTensor (intrinsic definition)Scalar fieldEquation of stateGalaxyTheoretical physicsMathematical physicsClassical mechanicsAstrophysicsAnisotropyCosmologyQuantum mechanicsGeometryMathematicsCosmology and Gravitation TheoriesDark Matter and Cosmic PhenomenaGalaxies: Formation, Evolution, Phenomena