CWRU PAT Coffee Agenda

Tuesdays 10:30 - 11:30 | Fridays 11:30 - 12:30

+2 Consistent Modified Gravity Analysis of Anisotropic Galaxy Clustering Using BOSS DR11.

gds6 +1 aam80 +1

+2 The refractive index of relic gravitons.

aam80 +1 gds6 +1

+1 No-Scale Inflation.

kxp265 +1

+1 Finite Upper Bound for the Hawking Decay Time of an Arbitrarily Large Black Hole in Anti-de Sitter Spacetime.

aam80 +1

+1 Probing Modified Gravity with Atom-Interferometry: a Numerical Approach.

jtd55 +1

+1 RCSLenS: Testing gravitational physics through the cross-correlation of weak lensing and large-scale structure.

gds6 +1

+1 Stringent neutrino flux constraints on anti-quark nugget dark matter.

gds6 +1

Showing votes from 2015-07-10 12:30 to 2015-07-14 11:30 | Next meeting is Friday Jul 10th, 11:30 am.

users

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astro-ph.CO

  • Probing Modified Gravity with Atom-Interferometry: a Numerical Approach.- [PDF] - [Article]

    Sandrine Schlogel, Sebastien Clesse, Andre Fuzfa
     

    Refined constraints on chameleon theories are calculated for atom-interferometry experiments, using a numerical approach consisting in solving for a four-region model the static and spherically symmetric Klein-Gordon equation for the chameleon field. By modeling not only the test mass and the vacuum chamber but also its walls and the exterior environment, the method allows to probe new effects on the scalar field profile and the induced acceleration of atoms. In the case of a weakly perturbing test mass, the effect of the wall is to enhance the field profile and to lower the acceleration inside the chamber by up to one order of magnitude. In the thin-shell regime, significant deviations from the analytical estimations are found, even when measurements are realized in the immediate vicinity of the test mass. Close to the vacuum chamber wall, the acceleration becomes negative and potentially measurable. This prediction could be used to discriminate between fifth-force effects and systematic experimental uncertainties, by doing the experiment at several key positions inside the vacuum chamber. The influence of the wall thickness and density is also studied. For the chameleon potential $V(\phi) = \Lambda^{4+\alpha} / \phi^\alpha$ and a coupling function $A(\phi) = \exp(\phi /M)$, one finds $M \gtrsim 7 \times 10^{16}$ GeV, independently of the power-law index. For $V(\phi) = \Lambda^4 (1+ \Lambda/ \phi)$ one finds $M \gtrsim 4 \times 10^{16}$ GeV. Future experiments able to measure an acceleration $a \sim 10^{-11} \mathrm{m/s^2}$ would probe the chameleon parameter space up to the Planck scale. Our method can easily be extended to constrain other models with a screening mechanism, such as symmetron, dilaton and f(R) theories.

  • RCSLenS: Testing gravitational physics through the cross-correlation of weak lensing and large-scale structure.- [PDF] - [Article]

    Chris Blake, Shahab Joudaki, Catherine Heymans, Ami Choi, Thomas Erben, Joachim Harnois-Deraps, Hendrik Hildebrandt, Benjamin Joachimi, Reiko Nakajima, Ludovic van Waerbeke, Massimo Viola
     

    The unknown nature of dark energy motivates continued cosmological tests of large-scale gravitational physics. We present a new consistency check based on the relative amplitude of non-relativistic galaxy peculiar motions, measured via redshift-space distortion, and the relativistic deflection of light by those same galaxies traced by galaxy-galaxy lensing. We take advantage of the latest generation of deep, overlapping imaging and spectroscopic datasets, combining the Red Cluster Sequence Lensing Survey (RCSLenS), the Canada-France-Hawaii Telescope Lensing Survey (CFHTLenS), the WiggleZ Dark Energy Survey and the Baryon Oscillation Spectroscopic Survey (BOSS). We quantify the results using the "gravitational slip" statistic E_G, which we estimate as 0.48 +/- 0.10 at z=0.32 and 0.30 +/- 0.07 at z=0.57, the latter constituting the highest redshift at which this quantity has been determined. These measurements are consistent with the predictions of General Relativity, for a perturbed Friedmann-Robertson-Walker metric in a Universe dominated by a cosmological constant, which are E_G = 0.41 and 0.36 at these respective redshifts. The combination of redshift-space distortion and gravitational lensing data from current and future galaxy surveys will offer increasingly stringent tests of fundamental cosmology.

  • The refractive index of relic gravitons.- [PDF] - [Article]

    Massimo Giovannini
     

    The dynamical evolution of the refractive index of the tensor modes of the geometry produces a specific class of power spectra characterized by a blue (i.e. slightly increasing) slope which is directly determined by the competition of the slow-roll parameter and of the rate of variation of the refractive index. Throughout the conventional stages of the inflationary and post-inflationary evolution, the microwave background anisotropies measurements, the pulsar timing limits and the big-bang nucleosythesis constraints set stringent bounds on the refractive index and on its rate of variation. Within the physically allowed region of the parameter space the cosmic background of relic gravitons leads to a potentially large signal for the ground based detectors (in their advanced version) and for the proposed space-borne interferometers. Conversely, the lack of direct detection of the signal will set a qualitatively new bound on the dynamical variation of the refractive index.

  • Stringent neutrino flux constraints on anti-quark nugget dark matter.- [PDF] - [Article]

    P. W. Gorham, B.J. Rotter
     

    Strongly-interacting matter in the form of nuggets of nuclear-density material are not currently excluded as dark matter candidates in the ten gram to hundred kiloton mass range. A recent variation on quark nugget dark matter models postulates that a first-order imbalance between matter and antimatter at the quark-gluon phase transition in the early universe could lead to most of the dark matter bound into heavy (baryon number $B \sim 10^{25}$) anti-quark nuggets in the current epoch, explaining both the dark matter preponderance and the matter-antimatter asymmetry. Interactions of these massive objects with normal matter in the Earth and Sun will lead to annihilation and an associated neutrino flux in the $\sim 20-50$ MeV range. We calculate these fluxes for anti-quark nuggets of sufficient number density to account for the dark matter and find that current neutrino flux limits from Super-Kamiokande exclude these objects as major dark matter candidates at a high confidence level over a very wide range of masses. Anti-quark nuggets in the previously allowed mass range cannot account for more than $\sim 1/5$ of the dark matter flux.

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