Abstract
We analyse modelling techniques for the large-scale structure formed in scalartensor
theories of constant Brans-Dicke parameter which match the concordance model background
expansion history and produce a chameleon suppression of the gravitational modification
in high-density regions. Thereby, we use a mass and environment dependent chameleon
spherical collapse model, the Sheth-Tormen halo mass function and linear halo bias, the
Navarro-Frenk-White halo density profile, and the halo model. Furthermore, using the spherical
collapse model, we extrapolate a chameleon mass-concentration scaling relation from a
CDM prescription calibrated to N-body simulations. We also provide constraints on the
model parameters to ensure viability on local scales. We test our description of the halo
mass function and nonlinear matter power spectrum against the respective observables extracted
from large-volume and high-resolution N-body simulations in the limiting case of
f(R) gravity, corresponding to a vanishing Brans-Dicke parameter. We find good agreement
between the two; the halo model provides a good qualitative description of the shape of the
relative enhancement of the f(R) matter power spectrum with respect to CDM caused by
the extra attractive gravitational force but fails to recover the correct amplitude. Introducing
an effective linear power spectrum in the computation of the two-halo term to account for
an underestimation of the chameleon suppression at intermediate scales in our approach, we
accurately reproduce the measurements from the N-body simulations.
Original language | English |
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Journal | Journal of Cosmology and Astroparticle Physics |
Volume | 2014 |
Issue number | 3 |
DOIs | |
Publication status | Published - Mar 2014 |
Keywords
- power spectrum
- modified gravity