Adrianne Slyz

Redshift and luminosity evolution of the intrinsic alignments of galaxies in Horizon-AGN

Monthly Notices of the Royal Astronomical Society Oxford University Press 461:3 (2016) 2702-2721

Authors:

N Chisari, C Laigle, S Codis, Y Dubois, J Devriendt, Lance Miller, K Benabed, A Slyz, R Gavazzi, C Pichon

Abstract:

Intrinsic galaxy shape and angular momentum alignments can arise in cosmological large-scale structure due to tidal interactions or galaxy formation processes. Cosmological hydrodynamical simulations have recently come of age as a tool to study these alignments and their contamination to weak gravitational lensing. We probe the redshift and luminosity evolution of intrinsic alignments in Horizon-AGN between z=0 and z=3 for galaxies with an r-band absolute magnitude of <-20. Alignments transition from being radial at low redshifts and high luminosities, dominated by the contribution of ellipticals, to being tangential at high redshift and low luminosities, where discs dominate the signal. This cannot be explained by the evolution of the fraction of ellipticals and discs alone: intrinsic evolution in the amplitude of alignments is necessary. The alignment amplitude of elliptical galaxies alone is smaller in amplitude by a factor of ~2, but has similar luminosity and redshift evolution as in current observations and in the nonlinear tidal alignment model at projected separations of > 1 Mpc. Alignments of discs are null in projection and consistent with current low redshift observations. The combination of the two populations yields an overall amplitude a factor of ~4 lower than observed alignments of luminous red galaxies with a steeper luminosity dependence. The restriction on accurate galaxy shapes implies that the galaxy population in the simulation is complete only to an r-band absolute magnitude of <-20. Higher resolution simulations will be necessary to avoid extrapolation of the intrinsic alignment predictions to the range of luminosities probed by future surveys.

Erratum: Towards simulating star formation in turbulent high-z galaxies with mechanical supernova feedback

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 459:1 (2016) 256-256

Authors:

Taysun Kimm, Renyue Cen, Julien Devriendt, Yohan Dubois, Adrianne Slyz

The Horizon-AGN simulation: evolution of galaxy properties over cosmic time

(2016)

Authors:

S Kaviraj, C Laigle, T Kimm, JEG Devriendt, Y Dubois, C Pichon, A Slyz, E Chisari, S Peirani

Comparing Simulations of AGN Feedback

(2016)

Authors:

Mark LA Richardson, Evan Scannapieco, Julien Devriendt, Adrianne Slyz, Robert J Thacker, Yohan Dubois, James Wurster, Joseph Silk

Radio continuum surveys and galaxy evolution: modelling and simulations

Proceedings of Science Sissa Medialab 267 (2016) 1-12

Authors:

Adrianne Slyz, Julien Devriendt, Matthew Jarvis, Y Dubois, C Pichon

Abstract:

We predict the evolution of the radio continuum sky at 1.4 GHz from the Horizon-AGN Adaptive Mesh Refinement (AMR) cosmological hydrodynamical simulation of a cubic volume of the Universe 100h−1 Mpc on a side. With empirically motivated models for the radio continuum emission due to both star formation and Active Galactic Nuclei (AGN), we estimate the contribution of each of these processes to the local radio continuum luminosity function (LF) and describe its evolution up to redshift 4. Despite the simplicity of these models, we find that our predictions for the local luminosity function are fairly consistent with Mauch & Sadler (2007) observations, with the faint end of the luminosity function dominated by star forming galaxies and the bright end by radio loud AGNs. At redshift one, a decent match to Smolcic et al. (2009) VLA data in the COSMOS field can only be achieved when we account for radio continuum emission from AGNs. We predict that the strongest evolution across the peak epoch of cosmic activity happens for low luminosity star forming galaxies L1.4GHz < 1022 W Hz−1 , whose contribution rises until z ∼ 2 and declines at higher redshifts. The contribution of low luminosity AGNs L1.4GHz < 1022 W Hz−1 steadily declines from z = 0 throughout the redshift range, whilst that of radio loud objects with luminosities in the range 1022 W Hz−1 < L1.4GHz < 1024 W Hz−1 rises dramatically until z = 4. Finally, high-luminosity radio loud AGNs, with L1.4GHz > 1024 W Hz−1 show surprisingly little evolution from z = 0 to z = 4.