1,886 research outputs found
Cosmological simulations of screened modified gravity out of the static approximation: effects on matter distribution
In the context of scalar tensor theories for gravity, there is a universally
adopted hypothesis when running N-body simulations that time derivatives in the
equation of motion for the scalar field are negligible. In this work we propose
to test this assumption for one specific scalar-tensor model with a gravity
screening mechanism: the symmetron. To this end, we implemented the necessary
modifications to include the non-static terms in the N-body code Ramses. We
present test cases and results from cosmological simulations. Our main finding
when comparing static vs. non-static simulations is that the global power
spectrum is only slightly modified when taking into account the inclusion of
non-static terms. On the contrary, we find that the calculation of the local
power spectrum gives different measurements. Such results imply one must be
careful when assuming the quasi-static approximation when investigating the
environmental effects of modified gravity and screening mechanisms in structure
formation of halos and voids distributions.Comment: 12 pages, 8 figures, matches version accepted for publication in PR
Shape of Clusters as a Probe of Screening Mechanisms in Modified Gravity
Scalar fields are crucial components in high energy physics and extensions of
General Relativity. The fact they are not observed in the solar system may be
due to a mechanism which screens their presence in high dense regions. We show
how observations of the ellipticity of galaxy clusters can discriminate between
models with and without scalar fields and even between different screening
mechanisms. Using nowadays X-ray observations we put novel constraints on the
different models.Comment: 4 pages, 3 figures, matches version accepted for publication in PR
Cosmological simulations with hydrodynamics of screened scalar-tensor gravity with non-universal coupling
In this paper we study the effects of letting the dark matter and the gas in
the Universe couple to the scalar field of the symmetron model, a modified
gravity theory, with varying coupling strength. We also search for a way to
distinguish between universal and non-universal couplings in observations. The
research is performed utilising a series of hydrodynamic, cosmological N-Body
simulations, studying the resulting power spectra and galaxy halo properties,
such as the density and temperature profiles. Results show that in the cases of
universal couplings, the deviations in the baryon fraction from CDM
are smaller than in the cases of non-universal couplings throughout the halos.
The same is apparent in the power spectrum baryon bias, defined as the ratio of
gas to dark matter power spectrum. Deviations of the density profiles and power
spectra from the CDM reference values can differ significantly between
dark matter and gas because the dark matter deviations are mostly larger than
the deviations in the gas.Comment: Updated following referee reports, results unchange
Strongly Coupled Chameleon Fields: New Horizons in Scalar Field Theory
We show that as a result of non-linear self-interactions, scalar field
theories that couple to matter much more strongly than gravity are not only
viable but could well be detected by a number of future experiments, provided
these are properly designed to do so.Comment: 4 pages, 3 figs. Typos corrected. Comments added. Phys. Rev. Lett. in
prin
CMB statistics in noncommutative inflation
Noncommutative geometry can provide effective description of physics at very
short distances taking into account generic effects of quantum gravity.
Inflation amplifies tiny quantum fluctuations in the early universe to
macroscopic scales and may thus imprint high energy physics signatures in the
cosmological perturbations that could be detected in the CMB. It is shown here
that this can give rise to parity-violating modulations of the primordial
spectrum and odd non-Gaussian signatures. The breaking of rotational invariance
of the CMB provides constraints on the scale of noncommutativity that are
competitive with the existing noncosmological bounds, and could explain the
curious hemispherical asymmetry that has been claimed to be observed in the
sky. This introduces also non-Gaussianity with peculiar shape- and
scale-dependence, which in principle allows an independent cross-check of the
presence of noncommutativity at inflation.Comment: 9 pages, no figure
DBI Galileons in the Einstein Frame: Local Gravity and Cosmology
It is shown that a disformally coupled theory in which the gravitational
sector has the Einstein-Hilbert form is equivalent to a quartic DBI Galileon
Lagrangian, possessing non-linear higher derivative interactions, and hence
allowing for the Vainshtein effect. This Einstein Frame description
considerably simplifies the dynamical equations and highlights the role of the
different terms. The study of highly dense, non-relativistic environments
within this description unravels the existence of a disformal screening
mechanism, while the study of static vacuum configurations reveals the
existence of a Vainshtein radius, at which the asymptotic solution breaks down.
Disformal couplings to matter also allow the construction of Dark Energy
models, which behave differently than conformally coupled ones and introduce
new effects on the growth of Large Scale Structure over cosmological scales, on
which the scalar force is not screened. We consider a simple Disformally
Coupled Dark Matter model in detail, in which standard model particles follow
geodesics of the gravitational metric and only Dark Matter is affected by the
disformal scalar field. This particular model is not compatible with
observations in the linearly perturbed regime. Nonetheless, disformally coupled
theories offer enough freedom to construct realistic cosmological scenarios,
which can be distinguished from the standard model through characteristic
signatures.Comment: Discussion on the Vainshtein effect added. 25 pages, 6 figures, 2
tables. Accepted for publication in PR
- …