121 research outputs found
Testing General Relativity with Current Cosmological Data
Deviations from general relativity, such as could be responsible for the
cosmic acceleration, would influence the growth of large scale structure and
the deflection of light by that structure. We clarify the relations between
several different model independent approaches to deviations from general
relativity appearing in the literature, devising a translation table. We
examine current constraints on such deviations, using weak gravitational
lensing data of the CFHTLS and COSMOS surveys, cosmic microwave background
radiation data of WMAP5, and supernova distance data of Union2. Markov Chain
Monte Carlo likelihood analysis of the parameters over various redshift ranges
yields consistency with general relativity at the 95% confidence level.Comment: 11 pages; 7 figures; typographical errors corrected; this is the
published versio
Tests of Modified Gravity with Dwarf Galaxies
In modified gravity theories that seek to explain cosmic acceleration, dwarf
galaxies in low density environments can be subject to enhanced forces. The
class of scalar-tensor theories, which includes f(R) gravity, predict such a
force enhancement (massive galaxies like the Milky Way can evade it through a
screening mechanism that protects the interior of the galaxy from this "fifth"
force). We study observable deviations from GR in the disks of late-type dwarf
galaxies moving under gravity. The fifth-force acts on the dark matter and HI
gas disk, but not on the stellar disk owing to the self-screening of main
sequence stars. We find four distinct observable effects in such disk galaxies:
1. A displacement of the stellar disk from the HI disk. 2. Warping of the
stellar disk along the direction of the external force. 3. Enhancement of the
rotation curve measured from the HI gas compared to that of the stellar disk.
4. Asymmetry in the rotation curve of the stellar disk. We estimate that the
spatial effects can be up to 1 kpc and the rotation velocity effects about 10
km/s in infalling dwarf galaxies. Such deviations are measurable: we expect
that with a careful analysis of a sample of nearby dwarf galaxies one can
improve astrophysical constraints on gravity theories by over three orders of
magnitude, and even solar system constraints by one order of magnitude. Thus
effective tests of gravity along the lines suggested by Hui et al (2009) and
Jain (2011) can be carried out with low-redshift galaxies, though care must be
exercised in understanding possible complications from astrophysical effects.Comment: 26 pages, 9 figure
Cluster Density Profiles as a Test of Modified Gravity
We present a new test of gravitational interactions at the r\sim(0.2-20)Mpc
scale, around the virial radius of dark matter halos measured through
cluster-galaxy lensing of maxBCG clusters from the Sloan Digital Sky Survey
(SDSS). We employ predictions from self-consistent simulations of f(R) gravity
to find an upper bound on the background field amplitude of f_R0<3.5x10^-3 at
the 1D-marginalized 95% confidence level. As a model-independent assessment of
the constraining power of cluster profiles measured through weak gravitational
lensing, we also constrain the amplitude F_0 of a phenomenological modification
based on the profile enhancement induced by f(R) gravity when not including
effects from the increased cluster abundance in f(R). In both scenarios,
dark-matter-only simulations of the concordance model corresponding to f_R0=0
and F_0=0 are consistent with the lensing measurements, i.e., at the 68% and
95% confidence level, respectively.Comment: 19 pages, 10 figures, 3 tables; new figure added to new version,
removed F_0>0 prio
The speed of Galileon gravity
We analyse the speed of gravitational waves in coupled Galileon models with an equation of state ωphgr=−1 now and a ghost-free Minkowski limit. We find that the gravitational waves propagate much faster than the speed of light unless these models are small perturbations of cubic Galileons and the Galileon energy density is sub-dominant to a dominant cosmological constant. In this case, the binary pulsar bounds on the speed of gravitational waves can be satisfied and the equation of state can be close to -1 when the coupling to matter and the coefficient of the cubic term of the Galileon Lagrangian are related. This severely restricts the allowed cosmological behaviour of Galileon models and we are forced to conclude that Galileons with a stable Minkowski limit cannot account for the observed acceleration of the expansion of the universe on their own. Moreover any sub-dominant Galileon component of our universe must be dominated by the cubic term. For such models with gravitons propagating faster than the speed of light, the gravitons become potentially unstable and could decay into photon pairs. They could also emit photons by Cerenkov radiation. We show that the decay rate of such speedy gravitons into photons and the Cerenkov radiation are in fact negligible. Moreover the time delay between the gravitational signal and light emitted by explosive astrophysical events could serve as a confirmation that a modification of gravity acts on the largest scales of the Universe
Confirmation of general relativity on large scales from weak lensing and galaxy velocities
Although general relativity underlies modern cosmology, its applicability on
cosmological length scales has yet to be stringently tested. Such a test has
recently been proposed, using a quantity, EG, that combines measures of
large-scale gravitational lensing, galaxy clustering and structure growth rate.
The combination is insensitive to 'galaxy bias' (the difference between the
clustering of visible galaxies and invisible dark matter) and is thus robust to
the uncertainty in this parameter. Modified theories of gravity generally
predict values of EG different from the general relativistic prediction
because, in these theories, the 'gravitational slip' (the difference between
the two potentials that describe perturbations in the gravitational metric) is
non-zero, which leads to changes in the growth of structure and the strength of
the gravitational lensing effect3. Here we report that EG = 0.39 +/- 0.06 on
length scales of tens of megaparsecs, in agreement with the general
relativistic prediction of EG 0.4. The measured value excludes a
model within the tensor-vector-scalar gravity theory, which modifies both
Newtonian and Einstein gravity. However, the relatively large uncertainty still
permits models within f(R) theory, which is an extension of general relativity.
A fivefold decrease in uncertainty is needed to rule out these models.Comment: Submitted version; 13 pages, 2 figures. Accepted version and
supplementary material are available at:
http://www.nature.com/nature/journal/v464/n7286/full/nature08857.html
Euclid:Constraining linearly scale-independent modifications of gravity with the spectroscopic and photometric primary probes
The future Euclid space satellite mission will offer an invaluable opportunity to constrain modifications to general relativity at cosmic scales. We focus on modified gravity models characterised, at linear scales, by a scale-independent growth of perturbations while featuring different testable types of derivative screening mechanisms at smaller nonlinear scales. We consider 3 specific models, namely Jordan-Brans-Dicke (JBD), the normal branch of Dvali-Gabadadze-Porrati (nDGP) gravity and -mouflage (KM) gravity. We provide forecasts from spectroscopic and photometric primary probes by Euclid on the cosmological parameters and the extra parameters of the models, respectively, , and , which quantify the deviations from general relativity. This analysis will improve our knowledge of the cosmology of these modified gravity models. The forecasts analysis employs the Fisher matrix method applied to weak lensing (WL); photometric galaxy clustering (GC); spectroscopic galaxy clustering (GC) and the cross-correlation (XC) between GC and WL. For the Euclid survey specifications we define three scenarios, characterised by different cuts in and , to assess the constraining power of nonlinear scales. For each model we consider two fiducial values for the corresponding model parameter. In an optimistic setting at 68.3\% confidence interval, with Euclid alone we find the following percentage relative errors: for , with a fiducial value of , 35% using GC alone, 3.6% using GC+WL+XC and 3.3% using GC+WL+XC+GC; for , with a fiducial value of , we find respectively 90%, 20% and 17%; finally, for respectively 5%, 0.15% and 0.14%. (abridged
Tests of chameleon gravity
Theories of modified gravity, where light scalars with non-trivial self-interactions and non-minimal couplings to matter—chameleon and symmetron theories—dynamically suppress deviations from general relativity in the solar system. On other scales, the environmental nature of the screening means that such scalars may be relevant. The highly-nonlinear nature of screening mechanisms means that they evade classical fifth-force searches, and there has been an intense effort towards designing new and novel tests to probe them, both in the laboratory and using astrophysical objects, and by reinterpreting existing datasets. The results of these searches are often presented using different parametrizations, which can make it difficult to compare constraints coming from different probes. The purpose of this review is to summarize the present state-of-the-art searches for screened scalars coupled to matter, and to translate the current bounds into a single parametrization to survey the state of the models. Presently, commonly studied chameleon models are well-constrained but less commonly studied models have large regions of parameter space that are still viable. Symmetron models are constrained well by astrophysical and laboratory tests, but there is a desert separating the two scales where the model is unconstrained. The coupling of chameleons to photons is tightly constrained but the symmetron coupling has yet to be explored. We also summarize the current bounds on f(R) models that exhibit the chameleon mechanism (Hu and Sawicki models). The simplest of these are well constrained by astrophysical probes, but there are currently few reported bounds for theories with higher powers of R. The review ends by discussing the future prospects for constraining screened modified gravity models further using upcoming and planned experiments
Euclid Preparation. TBD. Impact of magnification on spectroscopic galaxy clustering
In this paper we investigate the impact of lensing magnification on the analysis of Euclid's spectroscopic survey, using the multipoles of the 2-point correlation function for galaxy clustering. We determine the impact of lensing magnification on cosmological constraints, and the expected shift in the best-fit parameters if magnification is ignored. We consider two cosmological analyses: i) a full-shape analysis based on the CDM model and its extension CDM and ii) a model-independent analysis that measures the growth rate of structure in each redshift bin. We adopt two complementary approaches in our forecast: the Fisher matrix formalism and the Markov chain Monte Carlo method. The fiducial values of the local count slope (or magnification bias), which regulates the amplitude of the lensing magnification, have been estimated from the Euclid Flagship simulations. We use linear perturbation theory and model the 2-point correlation function with the public code coffe. For a CDM model, we find that the estimation of cosmological parameters is biased at the level of 0.4-0.7 standard deviations, while for a CDM dynamical dark energy model, lensing magnification has a somewhat smaller impact, with shifts below 0.5 standard deviations. In a model-independent analysis aiming to measure the growth rate of structure, we find that the estimation of the growth rate is biased by up to standard deviations in the highest redshift bin. As a result, lensing magnification cannot be neglected in the spectroscopic survey, especially if we want to determine the growth factor, one of the most promising ways to test general relativity with Euclid. We also find that, by including lensing magnification with a simple template, this shift can be almost entirely eliminated with minimal computational overhead
Euclid:Testing the Copernican principle with next-generation surveys
The Copernican principle, the notion that we are not at a special location in the Universe, is one of the cornerstones of modern cosmology and its violation would invalidate the Friedmann-Lemaître-Robertson-Walker (FLRW) metric, causing a major change in our understanding of the Universe. Thus, it is of fundamental importance to perform observational tests of this principle. We determine the precision with which future surveys will be able to test the Copernican principle and their ability to detect any possible violations. We forecast constraints on the inhomogeneous Lemaître-Tolman-Bondi model with a cosmological constant (LTB), basically a cosmological constant and cold dark matter (CDM) model, but endowed with a spherical inhomogeneity. We consider combinations of currently available data and simulated Euclid data, together with external data products, based on both CDM and LTB fiducial models. These constraints are compared to the expectations from the Copernican principle. When considering the CDM fiducial model, we find that Euclid data, in combination with other current and forthcoming surveys, will improve the constraints on the Copernican principle by about , with variations depending on the observables and scales considered. On the other hand, when considering a LTB fiducial model, we find that future Euclid data, combined with other current and forthcoming data sets, will be able to detect Gpc-scale inhomogeneities of contrast . Next-generation surveys, such as Euclid, will thoroughly test homogeneity at large scales, tightening the constraints on possible violations of the Copernican principle
Compact objects in scalar-tensor theories after GW170817
The recent observations of neutron star mergers have changed our perspective
on scalar- tensor theories of gravity, favouring models where gravitational
waves travel at the speed of light. In this work we consider a scalar-tensor
set-up with such a property, belonging to a beyond Horndeski system, and we
numerically investigate the physics of locally asymptotically flat black holes
and relativistic stars. We first determine regular black hole solutions
equipped with horizons: they are characterized by a deficit angle at infinity,
and by large contributions of the scalar to the geometry in the near horizon
region. We then study configurations of incompressible relativistic stars. We
show that their compactness can be much higher than stars with the same energy
density in General Relativity, and the scalar field profile imposes stringent
constraints on the star properties. These results can suggest new ways to probe
the efficiency of screening mechanisms in strong gravity regimes, and can help
to build specific observational tests for scalar-tensor gravity models with
unit speed for gravitational waves.Comment: 20 pages, 6 figure
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