Adaptive optics imaging and optical spectroscopy of a multiple merger in a luminous infrared galaxy

TL;DR

This study uses multi-wavelength imaging and spectroscopy to analyze a complex triple merger in a luminous infrared galaxy, revealing detailed dynamics, star formation, and interaction features that distinguish it from typical ULIRGs.

Contribution

It provides a detailed multi-wavelength analysis of a triple merger galaxy, highlighting the unique star formation distribution and interaction scenario, aided by simulations.

Findings

The system is a triple merger with a star formation peak in the irregular component.

No evidence of AGN activity was found in the system.

The star formation rate is approximately 190 solar masses per year.

Abstract

(abridged) We present near-infrared (NIR) adaptive optics imaging obtained with VLT/NACO and optical spectroscopy from the Southern African Large Telescope (SALT) of a luminous infrared galaxy (LIRG) IRAS 19115-2124. These data are combined with archival HST imaging and Spitzer imaging and spectroscopy, allowing us to study this disturbed interacting/merging galaxy, dubbed the Bird, in extraordinary detail. In particular, the data reveal a triple system where the LIRG phenomenon is dominated by the smallest of the components. One nucleus is a regular barred spiral with significant rotation, while another is highly disturbed with a surface brightness distribution intermediate to that of disk and bulge systems, and hints of remaining arm/bar structure. We derive dynamical masses in the range 3-7x10^10 M_solar for both. The third component appears to be a 1-2x10^10 M_solar mass irregular galaxy. The total system exhibits HII galaxy-like optical line ratios and strengths, and no evidence for AGN activity is found from optical or mid-infrared data. The star formation rate is estimated to be 190 M_solar/yr. We search for SNe, super star clusters, and detect 100-300 km/s outflowing gas from the Bird. Overall, the Bird shows kinematic, dynamical, and emission line properties typical for cool ultra luminous IR galaxies. However, the interesting features setting it apart for future studies are its triple merger nature, and the location of its star formation peak - the strongest star formation does not come from the two major K-band nuclei, but from the third irregular component. Aided by simulations, we discuss scenarios where the irregular component is on its first high-speed encounter with the more massive components.