cad96

 

https://webcast.web.cern.ch/webcast/play.php?event=442432 

Asantha Cooray, Alexandra Abate, Boris Häußler, Jonathan R. Trump, Christina C. Williams, (2) Arizona, (3) ESO/Chile, (4) Penn State)

Astronomers in CANDELS outline changes for the academic system to promote a smooth transition for junior scientists from academia to industry. Donate to arXiv

Enrique Gaztanaga, Camille Bonvin, Lam Hui

It is usually assumed that in the linear regime the two-point correlation function of galaxies contains only a monopole, quadrupole and hexadecapole. Looking at cross-correlations between different populations of galaxies, this turns out not to be the case. In particular, the cross-correlations between a bright and a faint population of galaxies contain also a dipole. In this paper we present the first measurement of this dipole. We discuss the three types of effects that contribute to the dipole: relativistic distortions, evolution effects and wide-angle effects. We show that the relativistic distortions and the evolution effects are too small to be detected in the LOWz and CMASS sample of the BOSS survey. We discuss the convention-dependent nature of the wide-angle effect and we show that with the appropriate choice of kernel, a particular version of the wide-angle effect (that we call large-angle effect) can be significantly enhanced. We measure this effect in the dipole with a signal-to-noise of 50, which is as good as the one of the monopole. We emphasise that the large-angle dipole does not contain new statistical information, since it is just a geometrical combination of the monopole and the quadrupole. However it is conceivable that it is sensitive to different systematics. Donate to arXiv

Mustafa A. Amin, Daniel Baumann

We provide a statistical framework for characterizing stochastic particle production in the early universe via a precise correspondence to current conduction in wires with impurities. Our approach is particularly useful when the microphysics is uncertain and the dynamics are complex, but only coarse-grained information is of interest. We study scenarios with multiple interacting fields and derive the evolution of the particle occupation numbers from a Fokker-Planck equation. At late times, the typical occupation numbers grow exponentially which is the analog of Anderson localization for disordered wires. Some statistical features of the occupation numbers show hints of universality in the limit of a large number of interactions and/or a large number of fields. For test cases, excellent agreement is found between our analytic results and numerical simulations. Donate to arXiv

Alessandro Manzotti, Scott Dodelson, Youngsoo Park

Planned cosmic microwave background (CMB) experiments can dramatically improve what we know about neutrino physics, inflation, and dark energy. The low level of noise, together with improved angular resolution, will increase the signal to noise of the CMB polarized signal as well as the reconstructed lensing potential of high redshift large scale structure. Projected constraints on cosmological parameters are extremely tight, but these can be improved even further with information from external experiments. Here, we examine quantitatively the extent to which external priors can lead to improvement in projected constraints from a CMB-Stage IV (S4) experiment on neutrino and dark energy properties. We find that CMB S4 constraints on neutrino mass could be strongly enhanced by external constraints on the cold dark matter density $\Omega_{c}h^{2}$ and the Hubble constant $H_{0}$. If polarization on the largest scales ($\ell<50$) will not be measured, an external prior on the primordial amplitude $A_{s}$ or the optical depth $\tau$ will also be important. A CMB constraint on the number of relativistic degrees of freedom, $N_{\rm eff}$, will benefit from an external prior on the spectral index $n_{s}$ and the baryon energy density $\Omega_{b}h^{2}$. Finally, an external prior on $H_{0}$ will help constrain the dark energy equation of state ($w$). Donate to arXiv