Measuring Star-formation Rate and Far-Infrared Color in High-redshift Galaxies Using the CO (7-6) and [NII] 205 micron Lines

Abstract

To better characterize the global star formation (SF) activity in a galaxy, one needs to know not only the star formation rate (SFR) but also the rest-frame, far-infrared (FIR) color (e.g., the 60-to-100 μm color, C(60/100)] of the dust emission. The latter probes the average intensity of the dust heating radiation field and scales statistically with the effective SFR surface density in star-forming galaxies including (ultra-)luminous infrared galaxies [(U)LIRGs]. To this end, we exploit here a new spectroscopic approach involving only two emission lines: CO\,(7-6) at 372 μm and [NII] at 205 μm. For local (U)LIRGs, the ratios of the CO (7-6) luminosity (L CO\,(7-6)) to the total infrared luminosity (L IR; 8-1000 μm) are fairly tightly distributed (to within 0.12 dex) and show little dependence on C(60/100). This makes L CO\,(7-6) a good SFR tracer, which is less contaminated by active galactic nuclei (AGN) than L IR and may also be much less sensitive to metallicity than L CO\,(1-0). Furthermore, the logarithmic [NII] 205 μm to CO (7-6) luminosity ratio is fairly steeply (at a slope of -1.4) correlated with C(60/100), with a modest scatter (0.23 dex). This makes it a useful estimator on C(60/100) with an implied uncertainty of 0.15 [or 4 K in the dust temperature (T dust) in the case of a graybody emission with T dust 30 K and a dust emissivity index β 1]. Our locally calibrated SFR and C(60/100) estimators are shown to be consistent with the published data of (U)LIRGs of z up to 6.5.