Cosmology

MIGHTEE: The MeerKAT International GHz Tiered Extragalactic Exploration

IOP Conference Series Materials Science and Engineering IOP Publishing 198:1 (2017) 012014

Authors:

A Russ Taylor, Matt Jarvis

KiDS-450: Testing extensions to the standard cosmological model

Monthly Notices of the Royal Astronomical Society Oxford University Press (2017)

Authors:

Shahab Joudaki, Alexander Mead, Chris Blake, Ami Choi, Jelte de Jong, Thomas Erben, Catherine Heymans, Hendrik Hildebrandt, Henk Hoekstra, Benjamin Joachimi, Dominik Klaes, Fabian Köhlinger, Konrad Kuijken, John McFarland, Lance Miller, Peter Schneider, Massimo Viola

Abstract:

We test extensions to the standard cosmological model with weak gravitational lensing tomography using 450 deg$^2$ of imaging data from the Kilo Degree Survey (KiDS). In these extended cosmologies, which include massive neutrinos, nonzero curvature, evolving dark energy, modified gravity, and running of the scalar spectral index, we also examine the discordance between KiDS and cosmic microwave background measurements from Planck. The discordance between the two datasets is largely unaffected by a more conservative treatment of the lensing systematics and the removal of angular scales most sensitive to nonlinear physics. The only extended cosmology that simultaneously alleviates the discordance with Planck and is at least moderately favored by the data includes evolving dark energy with a time-dependent equation of state (in the form of the $w_0-w_a$ parameterization). In this model, the respective $S_8 = \sigma_8 \sqrt{\Omega_{\rm m}/0.3}$ constraints agree at the $1\sigma$ level, and there is `substantial concordance' between the KiDS and Planck datasets when accounting for the full parameter space. Moreover, the Planck constraint on the Hubble constant is wider than in LCDM and in agreement with the Riess et al. (2016) direct measurement of $H_0$. The dark energy model is moderately favored as compared to LCDM when combining the KiDS and Planck measurements, and remains moderately favored after including an informative prior on the Hubble constant. In both of these scenarios, the dark energy parameters are discrepant with a cosmological constant at the $3\sigma$ level. Moreover, KiDS constrains the sum of neutrino masses to 4.0 eV (95% CL), finds no preference for time or scale dependent modifications to the metric potentials, and is consistent with flatness and no running of the spectral index. The analysis code is publicly available at https://github.com/sjoudaki/kids450

Investigating the Unification of LOFAR-detected powerful AGN in the Boötes Field

Monthly Notices of the Royal Astronomical Society Oxford University Press 469:2 (2017) 1883-1896

Authors:

Leah K Morabito, WL Williams, KJ Duncan, HJA Röttgering, G Miley, A Saxena, P Barthel, PN Best, M Bruggen, G Brunetti, KT Chyży, D Engels, MJ Hardcastle, JJ Harwood, Matt J Jarvis, EK Mahony, I Prandoni, TW Shimwell, A Shulevski, C Tasse

Abstract:

Low radio frequency surveys are important for testing unified models of radio-loud quasars and radio galaxies. Intrinsically similar sources that are randomly oriented on the sky will have different projected linear sizes. Measuring the projected linear sizes of these sources provides an indication of their orientation. Steep-spectrum isotropic radio emission allows for orientation-free sample selection at low radio frequencies. We use a new radio survey of the Boötes field at 150 MHz made with the Low-Frequency Array (LOFAR) to select a sample of radio sources. We identify 60 radio sources with powers P > 10^25.5  W Hz^−1, at 150 MHz using cross-matched multiwavelength information from the AGN and Galaxy Evolution Survey, which provides spectroscopic redshifts and photometric identification of 16 quasars and 44 radio galaxies. When considering the radio spectral slope only, we find that radio sources with steep spectra have projected linear sizes that are on average 4.4 ± 1.4 larger than those with flat spectra. The projected linear sizes of radio galaxies are on average 3.1 ± 1.0 larger than those of quasars (2.0 ± 0.3 after correcting for redshift evolution). Combining these results with three previous surveys, we find that the projected linear sizes of radio galaxies and quasars depend on redshift but not on power. The projected linear size ratio does not correlate with either parameter. The LOFAR data are consistent within the uncertainties with theoretical predictions of the correlation between the quasar fraction and linear size ratio, based on an orientation-based unification scheme.

Implications of Strong Intergalactic Magnetic Fields for Ultra-High-Energy Cosmic-Ray Astronomy

(2017)

Authors:

Rafael Alves Batista, Min-Su Shin, Julien Devriendt, Dmitri Semikoz, Guenter Sigl

nIFTy Cosmology: the clustering consistency of galaxy formation models

Monthly Notices of the Royal Astronomical Society Oxford University Press 469:1 (2017) 749-762

Authors:

A Pujol, RA Skibba, E Gaztañaga, A Benson, J Blaizot, R Bower, J Carretero, FJ Castander, A Cattaneo, SA Cora, DJ Croton, W Cui, D Cunnama, GD Lucia, Julien Devriendt, PJ Elahi, A Font, F Fontanot, J Garcia-Bellido, ID Gargiulo, V Gonzalez-Perez, J Helly, BMB Henriques, M Hirschmann, A Knebe, J Lee, GA Mamon, P Monaco, J Onions, ND Padilla, FR Pearce, C Power, RS Somerville, C Srisawat, PA Thomas, E Tollet, CA Vega-Martínez, SK Yi

Abstract:

We present a clustering comparison of 12 galaxy formation models (including Semi-Analytic Models (SAMs) and Halo Occupation Distribution (HOD) models) all run on halo catalogues and merger trees extracted from a single {\Lambda}CDM N-body simulation. We compare the results of the measurements of the mean halo occupation numbers, the radial distribution of galaxies in haloes and the 2-Point Correlation Functions (2PCF). We also study the implications of the different treatments of orphan (galaxies not assigned to any dark matter subhalo) and non-orphan galaxies in these measurements. Our main result is that the galaxy formation models generally agree in their clustering predictions but they disagree significantly between HOD and SAMs for the orphan satellites. Although there is a very good agreement between the models on the 2PCF of central galaxies, the scatter between the models when orphan satellites are included can be larger than a factor of 2 for scales smaller than 1 Mpc/h. We also show that galaxy formation models that do not include orphan satellite galaxies have a significantly lower 2PCF on small scales, consistent with previous studies. Finally, we show that the 2PCF of orphan satellites is remarkably different between SAMs and HOD models. Orphan satellites in SAMs present a higher clustering than in HOD models because they tend to occupy more massive haloes. We conclude that orphan satellites have an important role on galaxy clustering and they are the main cause of the differences in the clustering between HOD models and SAMs.