Cosmology

The most massive galaxies in clusters are already fully grown at z similar to 0.5

MONTHLY NOTICES OF THE ROYAL ASTRONOMICAL SOCIETY 465:2 (2017) 2101-2119

Authors:

LJ Oldham, RCW Houghton, RL Davies

Measuring light echoes in NGC 4051

Monthly Notices of the Royal Astronomical Society Oxford University Press 467:4 (2017) 3924-3933

Authors:

TJ Turner, Lance Miller, JN Reeves, V Braito

Abstract:

Five archived X-ray observations of NGC 4051, taken using the NuSTAR observatory, have been analysed, revealing lags between flux variations in bands covering a wide range of X-ray photon energy. In all pairs of bands compared, the harder band consistently lags the softer band by at least 1000s, at temporal frequencies ~5E-5 Hz. In addition, soft-band lags up to 400s are measured at frequencies ~2E-4 Hz. Light echos from an excess of soft band emission in the inner accretion disk cannot explain the lags in these data, as they are seen in cross-correlations with energy bands where the softer band is expected to have no contribution from reflection. The basic properties of the time delays have been parameterised by fitting a top hat response function that varies with photon energy, taking fully into account the covariance between measured time lag values. The low-frequency hard-band lags and the transition to soft-band lags are consistent with time lags arising as reverberation delays from circumnuclear scattering of X-rays, although greater model complexity is required to explain the entire spectrum of lags. The scattered fraction increases with increasing photon energy as expected, and the scattered fraction is high, indicating the reprocessor to have a global covering fraction ~50% around the continuum source. Circumnuclear material, possibly associated with a disk wind at a few hundred gravitational radii from the primary X-ray source, may provide suitable reprocessing.

Galaxy-halo alignments in the Horizon-AGN cosmological hydrodynamical simulation

(2017)

Authors:

Nora Elisa Chisari, Nikolaos Koukoufilippas, Abhinav Jindal, Sebastien Peirani, Ricarda S Beckmann, Sandrine Codis, Julien Devriendt, Lance Miller, Yohan Dubois, Clotilde Laigle, Adrianne Slyz, Christophe Pichon

nIFTy Cosmology: the clustering consistency of galaxy formation models

(2017)

Authors:

Arnau Pujol, Ramin A Skibba, Enrique Gaztañaga, Andrew Benson, Jeremy Blaizot, Richard Bower, Jorge Carretero, Francisco J Castander, Andrea Cattaneo, Sofia A Cora, Darren J Croton, Weiguang Cui, Daniel Cunnama, Gabriella De Lucia, Julien E Devriendt, Pascal J Elahi, Andreea Font, Fabio Fontanot, Juan Garcia-Bellido, Ignacio D Gargiulo, Violeta Gonzalez-Perez, John Helly, Bruno MB Henriques, Michaela Hirschmann, Alexander Knebe, Jaehyun Lee, Gary A Mamon, Pierluigi Monaco, Julian Onions, Nelson D Padilla, Frazer R Pearce, Chris Power, Rachel S Somerville, Chaichalit Srisawat, Peter A Thomas, Edouard Tollet, Cristian A Vega-Martínez, Sukyoung K Yi

The KMOS Redshift One Spectroscopic Survey (KROSS): rotational velocities and angular momentum of z ≈ 0.9 galaxies★

Monthly Notices of the Royal Astronomical Society Oxford University Press 467:2 (2017) 1965-1983

Authors:

CM Harrison, HL Johnson, AM Swinbank, JP Stott, RG Bower, I Smail, AL Tiley, AJ Bunker, M Cirasuolo, D Sobral, RM Sharples, P Best, Martin Bureau, Matthew Jarvis, G Magdis

Abstract:

We present dynamical measurements for 586 Hα-detected star-forming galaxies from the KMOS (K-band Multi-Object Spectrograph) Redshift One Spectroscopic Survey (KROSS). The sample represents typical star-forming galaxies at this redshift (z = 0.6-1.0), with a median star formation rate of ≈7 M ⊙ yr -1 and a stellar mass range of log (M * [M ⊙ ]) ≈ 9-11. We find that the rotation velocity-stellar mass relationship (the inverse of the Tully- Fisher relationship) for our rotationally dominated sources (v C /σ 0 > 1) has a consistent slope and normalization as that observed for z = 0 discs. In contrast, the specific angular momentum (j * angular momentum divided by stellar mass) is ≈0.2-0.3 dex lower on average compared to z = 0 discs. The specific angular momentum scales as j s ∝ M * 0.6±0.2 , consistent with that expected for dark matter (i.e. j DM ∝ M DM 2/3 ). We find that z≈ 0.9 star-forming galaxies have decreasing specific angular momentum with increasing Sérsic index. Visually, the sources with the highest specific angular momentum, for a given mass, have the most disc-dominated morphologies. This implies that an angular momentum-mass-morphology relationship, similar to that observed in local massive galaxies, is already in place by z ≈ 1.