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Galileon Cosmology

Nathan Chow, Justin Khoury

Abstract

We study the cosmology of a galileon scalar-tensor theory, obtained by covariantizing the decoupling lagrangian of the Dvali-Gabadadze-Poratti (DGP) model. Despite being local in 3+1 dimensions, the resulting cosmological evolution is remarkably similar to that of the full 4+1-dimensional DGP framework, both for the expansion history and the evolution of density perturbations. As in the DGP model, the covariant galileon theory yields two branches of solutions, depending on the sign of the galileon velocity. Perturbations are stable on one branch and ghost-like on the other. An interesting effect uncovered in our analysis is a cosmological version of the Vainshtein screening mechanism: at early times, the galileon dynamics are dominated by self-interaction terms, resulting in its energy density being suppressed compared to matter or radiation; once the matter density has redshifted sufficiently, the galileon becomes an important component of the energy density and contributes to dark energy. We estimate conservatively that the resulting expansion history is consistent with the observed late-time cosmology, provided that the scale of modification satisfies r_c > 15 Gpc.

Galileon Cosmology

Abstract

We study the cosmology of a galileon scalar-tensor theory, obtained by covariantizing the decoupling lagrangian of the Dvali-Gabadadze-Poratti (DGP) model. Despite being local in 3+1 dimensions, the resulting cosmological evolution is remarkably similar to that of the full 4+1-dimensional DGP framework, both for the expansion history and the evolution of density perturbations. As in the DGP model, the covariant galileon theory yields two branches of solutions, depending on the sign of the galileon velocity. Perturbations are stable on one branch and ghost-like on the other. An interesting effect uncovered in our analysis is a cosmological version of the Vainshtein screening mechanism: at early times, the galileon dynamics are dominated by self-interaction terms, resulting in its energy density being suppressed compared to matter or radiation; once the matter density has redshifted sufficiently, the galileon becomes an important component of the energy density and contributes to dark energy. We estimate conservatively that the resulting expansion history is consistent with the observed late-time cosmology, provided that the scale of modification satisfies r_c > 15 Gpc.

Paper Structure

This paper contains 19 sections, 60 equations, 10 figures.

Table of Contents

  1. Introduction
  2. Decoupling Limit of DGP
  3. Self-screening effect
  4. Jordan frame description
  5. Non-linear Completion
  6. Cosmology
  7. Self-accelerated solution?
  8. Early-time solution and cosmological screening
  9. Cosmological screening
  10. Dynamical Attractor
  11. General stability analysis
  12. Numerical Analysis
  13. Results
  14. Comparison with DGP cosmology
  15. Growth of Density Perturbations
  16. ...and 4 more sections

Figures (10)

  • Figure 1: Result of numerically integrating the cosmological evolution equations with $r_c = 10$ Gpc. The solid curves denote the matter, radiation, cosmological constant and galileon energy density. The dotted line is the galileon energy density as predicted from the analytic solution.
  • Figure 2: Same as Fig. \ref{['rhos10']}, this time for $r_c = 20$ Gpc.
  • Figure 3: The fractional contributions to the total energy density from matter ($\Omega_{\rm m}$), radiation ($\Omega_{\rm r}$), cosmological constant ($\Omega_{\Lambda}$, dashed line) and the galileon field ($\Omega_{\pi}$, bold dashed line) for $r_c = 20$ Gpc, as a function of redshift.
  • Figure 4: The effective equation of state for the expansion history, defined in terms of the Hubble parameter by $\dot{H}/H^2 = -3(1+w_{\rm tot})/2$, for $\Lambda$CDM (solid), and the galileon model with $r_c = 10$ Gpc (dotted), 15 Gpc (dash-dotted) and 20 Gpc (dashed).
  • Figure 5: The effective BD parameter, $\omega_{\rm BD}^{\rm eff}$, with $r_c = 10$ Gpc (dotted), 15 Gpc (dash-dotted) and 20 Gpc (dashed).
  • ...and 5 more figures