Constraining the ISM properties of the Cloverleaf quasar host galaxy with Herschel spectroscopy

Abstract

We present Herschel observations of far-infrared (FIR) fine-structure (FS) lines [CII]158μm, [OI]63μm, [OIII]52μm, and [SiII]35μm in the z=2.56 Cloverleaf quasar, and combine them with published data in an analysis of the dense interstellar medium (ISM) in this system. Observed [CII]158μm, [OI]63μm, and FIR continuum flux ratios are reproduced with photodissociation region (PDR) models characterized by moderate far-ultraviolet (FUV) radiation fields G0= 0.3-1×103 and atomic gas densities n H= 3-5×103 cm-3, depending on contributions to [CII]158μm from ionized gas. We assess the contribution to [CII]158μm flux from an active galactic nucleus (AGN) narrow line region (NLR) using ground-based measurements of the [NII]122μm transition, finding that the NLR can contribute at most 20-30% of the observed [CII]158μm flux. The PDR density and far-UV radiation fields inferred from the atomic lines are not consistent with the CO emission, indicating that the molecular gas excitation is not solely provided via UV-heating from local star-formation, but requires an additional heating source. X-ray heating from the AGN is explored, and we find that X-ray dominated region (XDR) models, in combination with PDR models, can match the CO cooling without overproducing observed FS line emission. While this XDR/PDR solution is favored given the evidence for both X-rays and star-formation in the Cloverleaf, we also investigate alternatives for the warm molecular gas, finding that either mechanical heating via low-velocity shocks or an enhanced cosmic-ray ionization rate may also contribute. Finally, we include upper limits on two other measurements attempted in the Herschel program: [CII]158μm in FSC~10214 and [OI]63μm in APM~08279+5255.