Galaxy formation and evolution

Testing Quasar Unification: Radiative Transfer in Clumpy Winds

Chapter in DISC WINDS MATTER: MODELLING ACCRETION AND OUTFLOWS ON ALL SCALES, (2017) 143-167

Detailed H i kinematics of Tully–Fisher calibrator galaxies

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 463:4 (2016) 4052-4067

Authors:

Anastasia A Ponomareva, Marc AW Verheijen, Albert Bosma

In and out star formation in z~1.5 quiescent galaxies from rest-frame UV spectroscopy and the far-infrared

(2016)

Authors:

Raphael Gobat, Emanuele Daddi, Veronica Strazzullo, Bianca Garilli, Marco Mignoli, Zhongyang Ma, Shuowen Jin, Claudia Maraston, Georgios Magdis, Matthieu Béthermin, Michele Cappellari, Marcella Carollo, Andrea Cimatti, Chiara Feruglio, Michele Moresco, Masato Onodera, Lucia Pozzetti, Alvio Renzini, Mark Sargent, Francesco Valentino, Anita Zanella

Systematic trends in total-mass profiles from dynamical models of early-type galaxies

(2016)

Authors:

A Poci, M Cappellari, RM McDermid

Untangling galaxy components: full spectral bulge–disc decomposition

Monthly Notices of the Royal Astronomical Society Oxford University Press 466:2 (2016) 2024-2033

Authors:

M Tabor, M Merrifield, A Aragón-Salamanca, Michele Cappellari, SP Bamford, E Johnston

Abstract:

To ascertain whether photometric decompositions of galaxies into bulges and discs are astrophysically meaningful, we have developed a new technique to decompose spectral data cubes into separate bulge and disc components, subject only to the constraint that they reproduce the conventional photometric decomposition. These decompositions allow us to study the kinematic and stellar population properties of the individual components and how they vary with position, in order to assess their plausibility as discrete elements, and to start to reconstruct their distinct formation histories. An initial application of this method to Calar Alto Integral Field Area integral field unit observations of three isolated S0 galaxies confirms that in regions where both bulge and disc contribute significantly to the flux, they can be physically and robustly decomposed into a rotating dispersion-dominated bulge component and a rotating low-dispersion disc component. Analysis of the resulting stellar populations shows that the bulges of these galaxies have a range of ages relative to their discs, indicating that a variety of processes are necessary to describe their evolution. This simple test case indicates the broad potential for extracting from spectral data cubes the full spectral data of a wide variety of individual galaxy components, and for using such decompositions to understand the interplay between these various structures, and hence how such systems formed.