Martin Bureau

WISDOM Project - III: Molecular gas measurement of the supermassive black hole mass in the barred lenticular galaxy NGC4429

(2017)

Authors:

Timothy A Davis, Martin Bureau, Kyoko Onishi, Freeke van de Voort, Michele Cappellari, Satoru Iguchi, Lijie Liu, Eve V North, Marc Sarzi, Mark D Smith

A star formation study of the ATLAS3D early-type galaxies with the AKARI all-sky survey

Astronomy and Astrophysics EDP Sciences 605 (2017) A74

Authors:

T Kokusho, H Kaneda, Martin Bureau, T Suzuki, K Murata, A Kondo, M Yamagishi

Abstract:

The star formation properties of early-type galaxies (ETGs) are currently the subject of considerable interest, particularly whether they differ from those of gas-rich spirals. We perform a systematic study of star formation in a large sample of local ETGs using polycyclic aromatic hydrocarbon (PAH) and dust emission, focusing on the galaxies' star formation rates (SFRs) and star formation efficiencies (SFEs). Our sample is composed of the 260 ETGs from the ATLAS3D survey, from which we use the cold gas measurements (HI and CO). The SFRs are estimated from stellar, PAH and dust fits to spectral energy distributions created from new AKARI measurements and literature data from WISE and 2MASS. The mid-infrared luminosities of non-CO-detected galaxies are well correlated with their stellar luminosities, showing that they trace (circum)stellar dust emission. CO-detected galaxies show an excess above these correlations, uncorrelated with their stellar luminosities, indicating that they likely contain PAHs and dust of interstellar origin. PAH and dust luminosities of CO-detected galaxies show tight correlations with their molecular gas masses, and the derived current SFRs are typically 0.01-1 Msun/yr. These SFRs systematically decrease with stellar age at fixed stellar mass, while they correlate nearly linearly with stellar mass at fixed age. The majority of local ETGs follow the same star-formation law as local star-forming galaxies, and their current SFEs do not depend on either stellar mass or age. Our results clearly indicate that molecular gas is fueling current star formation in local ETGs, that appear to acquire this gas via mechanisms regulated primarily by stellar mass. The current SFEs of local ETGs are similar to those of local star-forming galaxies, indicating that their low SFRs are likely due to smaller cold gas fractions rather than a suppression of star formation.

The KMOS Redshift One Spectroscopic Survey (KROSS): the origin of disk turbulence in z~0.9 star-forming galaxies

(2017)

Authors:

HL Johnson, CM Harrison, AM Swinbank, AL Tiley, JP Stott, RG Bower, Ian Smail, AJ Bunker, D Sobral, OJ Turner, P Best, M Bureau, M Cirasuolo, MJ Jarvis, G Magdis, RM Sharples, J Bland-Hawthorn, B Catinella, L Cortese, SM Croom, C Federrath, K Glazebrook, SM Sweet, JJ Bryant, M Goodwin, IS Konstantopoulos, JS Lawrence, AM Medling, MS Owers, S Richards

A star formation study of the ATLAS3D early-type galaxies with the AKARI all-sky survey

(2017)

Authors:

Takuma Kokusho, Hidehiro Kaneda, Martin Bureau, Toyoaki Suzuki, Katsuhiro Murata, Akino Kondo, Mitsuyoshi Yamagishi

WISDOM Project – II. Molecular gas measurement of the supermassive black hole mass in NGC 4697

Monthly Notices of the Royal Astronomical Society Oxford University Press 468:4 (2017) 4675-4690

Authors:

TA Davis, Martin Bureau, K Onishi, Michele Cappellari, S Iguchi, M Sarzi

Abstract:

As part of the mm-Wave Interferometric Survey of Dark Object Masses (WISDOM) project, we present an estimate of the mass of the supermassive black hole (SMBH) in the nearby fast-rotating early-type galaxy NGC 4697. This estimate is based on Atacama Large Millimeter/submillimeter Array (ALMA) cycle-3 observations of the 12CO(2–1) emission line with a linear resolution of 29 pc (0.53 arcsec). We find that NGC 4697 hosts a small relaxed central molecular gas disc with a mass of 1.6 × 107 M⊙, co-spatial with the obscuring dust disc visible in optical Hubble Space Telescope imaging. We also resolve thermal 1 mm continuum emission from the dust in this disc. NGC 4697 is found to have a very low molecular gas velocity dispersion, σgas = 1.65+0.68−0.65 km s^−1. This seems to be partially because the giant molecular cloud mass function is not fully sampled, but other mechanisms such as chemical differentiation in a hard radiation field or morphological quenching also seem to be required. We detect a Keplerian increase of the rotation of the molecular gas in the very centre of NGC 4697, and use forward modelling of the ALMA data cube in a Bayesian framework with the KINematic Molecular Simulation (KINMS) code to estimate an SMBH mass of (1.3+0.18−0.17) × 108 M⊙ and an i-band mass-to-light ratio of 2.14+0.04−0.05M⊙/L⊙ (at the 99 per cent confidence level). Our estimate of the SMBH mass is entirely consistent with previous measurements from stellar kinematics. This increases confidence in the growing number of SMBH mass estimates being obtained in the ALMA era.