"Big Three Dragons": a z = 7.15 Lyman BreakGalaxy Detected in [OIII] 88 μm, [CII] 158 μm, and Dust Continuum with ALMA

Abstract

We present new ALMA observations and physical properties of a Lyman Break Galaxy at z=7.15. Our target, B14-65666, has a bright ultra-violet (UV) absolute magnitude, M UV≈-22.4, and has been spectroscopically identified in Lyα with a small rest-frame equivalent width of ≈4 . Previous HST image has shown that the target is comprised of two spatially separated clumps in the rest-frame UV. With ALMA, we have newly detected spatially resolved [OIII] 88 μm, [CII] 158 μm, and their underlying dust continuum emission. In the whole system of B14-65666, the [OIII] and [CII] lines have consistent redshifts of 7.15200.0003, and the [OIII] luminosity, (34.44.1)×108L , is about three times higher than the [CII] luminosity, (11.01.4)×108L . With our two continuum flux densities, the dust temperature is constrained to be T d≈50-60 K under the assumption of the dust emissivity index of β d=2.0-1.5, leading to a large total infrared luminosity of L TIR≈1×1012L . Owing to our high spatial resolution data, we show that the [OIII] and [CII] emission can be spatially decomposed into two clumps associated with the two rest-frame UV clumps whose spectra are kinematically separated by ≈200 km s-1. We also find these two clumps have comparable UV, infrared, [OIII], and [CII] luminosities. Based on these results, we argue that B14-65666 is a starburst galaxy induced by a major-merger. The merger interpretation is also supported by the large specific star-formation rate (defined as the star-formation rate per unit stellar mass), sSFR=260+119-57 Gyr-1, inferred from our SED fitting. Probably, a strong UV radiation field caused by intense star formation contributes to its high dust temperature and the [OIII]-to-[CII] luminosity ratio.