# ALMA view of RX J1131-1231: Sub-kpc CO (2-1) mapping of a molecular disk   in a lensed star-forming quasar host galaxy

**Authors:** D. Paraficz, M. Rybak, J. P. McKean, S. Vegetti, D. Sluse, F. Courbin,, H. R. Stacey, S. H. Suyu, M. Dessauges-Zavadsky, C. D. Fassnacht, L. V. E., Koopmans

arXiv: 1705.09931 · 2018-05-30

## TL;DR

This study uses ALMA imaging to map the molecular gas in a gravitationally lensed star-forming quasar host galaxy at z=0.654, revealing a rotating disk, complex gas structures, and insights into star formation and AGN feedback.

## Contribution

First detailed sub-kiloparsec CO (2-1) mapping of a lensed quasar host galaxy, combining lens modeling with dynamical analysis to understand gas distribution and star formation.

## Key findings

- Molecular gas forms a complete Einstein ring with differential magnification.
- The gas disk is consistent with rotation, with a maximum velocity of 280 km/s.
- Star formation rate is estimated at approximately 69 solar masses per year.

## Abstract

We present ALMA 2-mm continuum and CO (2-1) spectral line imaging of the gravitationally lensed z=0.654 star-forming/quasar composite RX J1131-1231 at 240-400 mas angular resolution. The continuum emission is found to be compact and coincident with the optical emission, whereas the molecular gas forms a complete Einstein ring, which shows strong differential magnification. The de-lensed source structure is determined on 400-pc resolution using a visibility-fitting lens modelling technique. The reconstructed molecular gas velocity-field is consistent with a rotating disk with a maximum rotational velocity of 280 km/s. From dynamical model fitting we find an enclosed mass M(r<5 kpc)=(1.46+/-0.31)*10^11 M_sol. The molecular gas distribution is highly structured, with clumps that are co-incident with higher gas velocity dispersion regions 40-50 km/s and with the intensity peaks in the optical emission, which are associated with sites of on-going turbulent star-formation. The peak in the CO (2-1) distribution is not co-incident with the AGN, where there is a paucity of molecular gas emission, possibly due to radiative feedback from the central engine. The intrinsic molecular gas luminosity is L'_CO=(1.2+/-0.3)*10^10 K km/s pc^2 and the inferred gas mass is M(H2)=(8.3+/-3.0)*10^10 M_sol, which given its dynamical mass is consistent with a CO-H2 conversion factor of alpha = 5.5+/-2.0 M_solar(K km/s pc^2)^-1. This suggests that the star-formation efficiency is dependent on the host galaxy morphology as opposed to the nature of the AGN. The far-infrared continuum spectral energy distribution shows evidence for heated dust, equivalent to an obscured star-formation rate of SFR=69^(+41)_(-25)*(7.3/u_IR)M_sol/yr, which demonstrates the composite star-forming/AGN nature of this system.   RX J1131-1231

## Full text

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## Figures

15 figures with captions in the complete paper: https://tomesphere.com/paper/1705.09931/full.md

## References

41 references — full list in the complete paper: https://tomesphere.com/paper/1705.09931/full.md

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Source: https://tomesphere.com/paper/1705.09931