The Submillimetre Properties of Ultraluminous Infrared Galaxies

TL;DR

This study presents submillimetre observations of local ULIRGs, revealing higher dust temperatures and smaller cold dust components compared to lower luminosity galaxies, and discusses their dust properties and contribution to the luminosity function.

Contribution

First comprehensive submm analysis of ULIRGs combining new and existing data, revealing their dust temperature, composition, and role in the luminosity function.

Findings

ULIRGs have higher dust temperatures (~42K) than lower luminosity galaxies (~35K).

ULIRGs possess smaller cold dust components compared to lower luminosity systems.

ULIRGs account for about 50% of the high-end 850 um luminosity function.

Abstract

We present the results of SCUBA observations of a complete sample of local ULIRGs. Twenty of the initial sample of 23 sources are detected at 850 um and nearly half of the objects are also detected at 450 um. This data is combined with existing observations of a further seven ULIRGs to produce the largest sample of submm observations of ULIRGs currently available. We use similar techniques to the SLUGS survey to fit dust spectral energy distributions (SEDs) to their far-IR emission. We find that ULIRGs have a higher dust temperature than lower luminosity objects (42K compared to 35K) and a steeper emissivity index. For those objects where 450 um fluxes are available we also attempt a two component dust SED fit, with warm and cool dust and a dust emissivity index of beta=2. Such a model has been found to be a good fit to lower luminosity systems. We find that it also works well for ULIRGs, but that ULIRGs have a smaller cold dust component. Comparison of the dust mass derived for ULIRGs and more normal spiral galaxies suggests that the dust content of a ULIRG is simply the combined dust content of the two galaxies whose merger has triggered the ULIRG activity. We examine the high end of the 850 um luminosity function and find results consistent with those of the earlier SLUGS survey. We also find that ULIRGs make up only about 50% of the high end of the 850 um luminosity function, with LIRGs containing a large mass of cool dust likely to be responsible for the rest.