Links

Tools

Export citation

Search in Google Scholar

A Herschel-ATLAS study of dusty spheroids: probing the minor-merger process in the local Universe

Journal article published in 2013 by S. Kaviraj, K. Rowlands, M. Alpaslan ORCID, L. Dunne, Ys-S. Ting, M. Bureau, S. Shabala, Cj J. Lintott, Djb J. B. Smith ORCID, N. Agius, R. Auld, Maarten Baes ORCID, N. Bourne, A. Cava, Dl L. Clements and other authors.
This paper is available in a repository.
This paper is available in a repository.

Full text: Download

Question mark in circle
Preprint: policy unknown
Upload
Question mark in circle
Postprint: policy unknown
Upload
Question mark in circle
Published version: policy unknown
Upload

Abstract

We use multiwavelength (0.12-500 mu m) photometry from Herschel-ATLAS, WISE, UKIDSS, SDSS and GALEX to study 23 nearby spheroidal galaxies with prominent dust lanes (DLSGs). DLSGs are considered to be remnants of recent minor mergers, making them ideal laboratories for studying both the interstellar medium (ISM) of spheroids and minor-merger-driven star formation in the nearby Universe. The DLSGs exhibit star formation rates (SFRs) between 0.01 and 10 M-circle dot yr(-1), with a median of 0.26 M-circle dot yr(-1) (a factor of 3.5 greater than the average SG). The median dust mass, dust-to-stellar mass ratio and dust temperature in these galaxies are around 10(7.6) M-circle dot, approximate to 0.05 per cent and approximate to 19.5 K, respectively. The dust masses are at least a factor of 50 greater than that expected from stellar mass loss and, like the SFRs, show no correlation with galaxy luminosity, suggesting that both the ISM and the star formation have external drivers. Adopting literature gas-to-dust ratios and star formation histories derived from fits to the panchromatic photometry, we estimate that the median current and initial gas-to-stellar mass ratios in these systems are approximate to 4 and approximate to 7 per cent, respectively. If, as indicated by recent work, minor mergers that drive star formation in spheroids with (NUV - r) > 3.8 (the colour range of our DLSGs) have stellar mass ratios between 1:6 and 1:10, then the satellite gas fractions are likely >= 50 per cent.