MID-INFRARED PROPERTIES OF NEARBY LUMINOUS INFRARED GALAXIES. I. SPITZER INFRARED SPECTROGRAPH SPECTRA FOR THE GOALS SAMPLE

The Great Observatories All-Sky LIRG Survey (GOALS) is a comprehensive, multiwavelength study of luminous infrared galaxies (LIRGs) in the local universe. Here we present low resolution Spitzer Infrared Spectrograph spectra covering 5–38 μm and provide a basic analysis of the mid-IR spectral properties observed for nearby LIRGs. In a companion paper, we discuss detailed fits to the spectra and compare the LIRGs to other classes of galaxies. The GOALS sample of 244 nuclei in 180 luminous (1011 ⩽ LIR/L☉ < 1012) and 22 ultraluminous (LIR/L☉ ⩾ 1012) IR galaxies represents a complete subset of the IRAS Revised Bright Galaxy Sample and covers a range of merger stages, morphologies, and spectral types. The majority (>60%) of the GOALS LIRGs have high 6.2 μm polycyclic aromatic hydrocarbon (PAH) equivalent widths (EQW6.2 μm > 0.4 μm) and low levels of silicate absorption (s9.7 μm > −1.0). There is a general trend among the U/LIRGs for both silicate depth and mid-infrared (MIR) slope to increase with increasing LIR. U/LIRGs in the late to final stages of a merger also have, on average, steeper MIR slopes and higher levels of dust obscuration. Together, these trends suggest that as gas and dust is funneled toward the center of a coalescing merger, the nuclei become more compact and more obscured. As a result, the dust temperature increases also leading to a steeper MIR slope. The sources that depart from these correlations have very low PAH equivalent width (EQW6.2 μm < 0.1 μm) consistent with their emission being dominated by an active galactic nucleus (AGN) in the MIR. These extremely low PAH EQW sources separate into two distinct types: relatively unobscured sources with a very hot dust component (and thus very shallow MIR slopes) and heavily dust obscured nuclei with a steep temperature gradient. The most heavily dust obscured sources are also the most compact in their MIR emission, suggesting that the obscuring (cool) dust is associated with the outer regions of the starburst and not simply a measure of the dust along the line of sight through a large, dusty disk. A marked decline is seen for the fraction of high EQW (star formation dominated) sources as the merger progresses. The decline is accompanied by an increase in the fraction of composite sources while the fraction of sources where an AGN dominates the MIR emission remains low. When compared to the MIR spectra of submillimeter galaxies (SMGs) at z ∼ 2, both the average GOALS LIRG and ULIRG spectra are more absorbed at 9.7 μm and the average GOALS LIRG has more PAH emission. However, when the AGN contributions to both the local GOALS LIRGs and the high-z SMGs are removed, the average local starbursting LIRG closely resembles the starburst-dominated SMGs.

[1]  S. Veilleux,et al.  THE SPATIAL EXTENT OF (U)LIRGS IN THE MID-INFRARED. II. FEATURE EMISSION , 2011, 1107.5958.

[2]  S. Veilleux,et al.  C-GOALS: Chandra observations of a complete sample of luminous infrared galaxies from the IRAS Revised Bright Galaxy Survey , 2011, 1103.2755.

[3]  B. Madore,et al.  MID-INFRARED SPECTRAL DIAGNOSTICS OF LUMINOUS INFRARED GALAXIES , 2010, 1012.1891.

[4]  A. Evans,et al.  THE NUCLEAR STRUCTURE IN NEARBY LUMINOUS INFRARED GALAXIES: HUBBLE SPACE TELESCOPE NICMOS IMAGING OF THE GOALS SAMPLE , 2010, 1012.4012.

[5]  E. Wright,et al.  INFRARED LUMINOSITIES AND AROMATIC FEATURES IN THE 24 μm FLUX-LIMITED SAMPLE OF 5MUSES , 2010, 1009.1633.

[6]  Ipac,et al.  THE SPATIAL EXTENT OF (U)LIRGs IN THE MID-INFRARED. I. THE CONTINUUM EMISSION , 2010, 1009.0038.

[7]  Kevin Xu,et al.  THE GREAT OBSERVATORIES ALL-SKY LIRG SURVEY: COMPARISON OF ULTRAVIOLET AND FAR-INFRARED PROPERTIES , 2010, 1004.0985.

[8]  Christopher D. Martin,et al.  POLYCYCLIC AROMATIC HYDROCARBONS IN GALAXIES AT z ∼ 0.1: THE EFFECT OF STAR FORMATION AND ACTIVE GALACTIC NUCLEI , 2009, 0909.2279.

[9]  J. Bernard-Salas,et al.  A SPITZER HIGH-RESOLUTION MID-INFRARED SPECTRAL ATLAS OF STARBURST GALAXIES , 2009, 0908.2812.

[10]  S. Veilleux,et al.  SPITZER QUASAR AND ULIRG EVOLUTION STUDY (QUEST). IV. COMPARISON OF 1 Jy ULTRALUMINOUS INFRARED GALAXIES WITH PALOMAR-GREEN QUASARS , 2009, 0905.1577.

[11]  L. Kewley,et al.  GOALS: The Great Observatories All-Sky LIRG Survey , 2009, 0904.4498.

[12]  I. Smail,et al.  MID-INFRARED SPECTROSCOPY OF SUBMILLIMETER GALAXIES: EXTENDED STAR FORMATION IN MASSIVE HIGH-REDSHIFT GALAXIES , 2009, 0903.4017.

[13]  B. Magnelli,et al.  The 0.4 < z < 1.3 star formation history of the Universe as viewed in the far-infrared , 2009, 0901.1543.

[14]  J. Surace,et al.  HST NICMOS Imaging of z ~ 2, 24 μm-selected Ultraluminous Infrared Galaxies , 2008, 0802.1050.

[15]  D. Elbaz,et al.  Mid-Infrared Spectral Diagnosis of Submillimeter Galaxies , 2007, 0711.1553.

[16]  H. Roussel,et al.  Spectral Mapping Reconstruction of Extended Sources , 2007, 0708.3745.

[17]  J. Bernard-Salas,et al.  PAH Emission from Ultraluminous Infrared Galaxies , 2007, 0707.4190.

[18]  B. Madore,et al.  Tracing Polycyclic Aromatic Hydrocarbons and Warm Dust Emission in the Seyfert Galaxy NGC 1068 , 2007, 0707.3440.

[19]  J. Bernard-Salas,et al.  Decomposing Dusty Galaxies. I. Multicomponent Spectral Energy Distribution Fitting , 2007, 0707.2962.

[20]  G. Helou,et al.  The Infrared Luminosity Function of Galaxies at Redshifts z = 1 and z ~ 2 in the GOODS Fields , 2007, astro-ph/0701283.

[21]  MID-INFRARED GALAXY CLASSIFICATION BASED ON SILICATE OBSCURATION AND PAH EQUIVALENT WIDTH , 2006, astro-ph/0611918.

[22]  Jr.,et al.  The Mid-Infrared Spectrum of Star-forming Galaxies: Global Properties of Polycyclic Aromatic Hydrocarbon Emission , 2006, astro-ph/0610913.

[23]  J. Bernard-Salas,et al.  The Mid-Infrared Properties of Starburst Galaxies from Spitzer-IRS Spectroscopy , 2006 .

[24]  A. Evans,et al.  Dense Molecular Gas and the Role of Star Formation in the Host Galaxies of Quasi-stellar Objects , 2006, astro-ph/0608453.

[25]  The Detection of Crystalline Silicates in Ultraluminous Infrared Galaxies , 2005, astro-ph/0509859.

[26]  Tucson,et al.  Infrared Luminosity Functions from the Chandra Deep Field-South: The Spitzer View on the History of Dusty Star Formation at 0 ≲ z ≲ 1* , 2005, astro-ph/0506462.

[27]  C. Grillmair,et al.  Observations of Ultraluminous Infrared Galaxies with the Infrared Spectrograph on the Spitzer Space Telescope. II. The IRAS Bright Galaxy Sample , 2006, astro-ph/0610218.

[28]  G. Helou,et al.  Nascent Starbursts in Synchrotron-deficient Galaxies with Hot Dust , 2003 .

[29]  J. Surace,et al.  The IRAS Revised Bright Galaxy Sample , 2003, astro-ph/0306263.

[30]  A. Tielens,et al.  The obscured mid-infrared continuum of NGC 4418 : A dust- and ice-enshrouded AGN , 2000, astro-ph/0012011.

[31]  D. Rigopoulou,et al.  A Large Mid-Infrared Spectroscopic and Near-Infrared Imaging Survey of Ultraluminous Infrared Galaxies: Their Nature and Evolution , 1999, astro-ph/9908300.

[32]  D. Kunze,et al.  What Powers Ultraluminous IRAS Galaxies? , 1997, astro-ph/9711255.

[33]  D. Sanders,et al.  LUMINOUS INFRARED GALAXIES , 1996 .

[34]  G. Neugebauer,et al.  Visual and Near-Infrared Imaging of Ultraluminous Infrared Galaxies: The IRAS 2 Jy Sample , 1996 .

[35]  G. Neugebauer,et al.  Ultraluminous infrared galaxies and the origin of quasars , 1988 .