Characterising the molecular line emission in the asymmetric Oph-IRS 48 dust trap: Temperatures, timescales, and sub-thermal excitation

Abstract

The ongoing physical and chemical processes in planet-forming disks set the stage for planet formation. The asymmetric disk around the young star Oph-IRS 48 has one of the most well-characterised chemical inventories, showing molecular emission from a wide variety of species at the dust trap. One of the explanations for the asymmetric structure is dust trapping by a perturbation-induced vortex. We aim to constrain the excitation properties of the molecular species SO2, CH3OH, and H2CO. We further characterise the extent of the molecular emission, through the determination of important physical and chemical timescales at the location of the dust trap. We also investigate whether the potential vortex can influence the observable temperature structure of the gas. Through a pixel-by-pixel rotational diagram analysis, we create rotational temperature and column density maps for SO2 and CH3OH, while temperature maps for H2CO are created using line ratios. We find temperatures of T55 K and T125 K for SO2 and CH3OH, respectively, while the line ratios point towards temperatures of T150-300 K for H2CO. The rotational diagram of CH3OH is dominated by scatter and subsequent non-LTE RADEX calculations suggest that both CH3OH and H2CO must be sub-thermally excited. The temperatures suggest that SO2 comes from a layer deep in the disk, while CH3OH and H2CO originate from a higher layer. While a potential radial gradient is seen in the temperature map of SO2, we do not find any hints of a vortex influencing the temperature structure. The determined turbulent mixing timescale is not able to explain the emitting heights of the molecules, but the photodissociation timescales are able to explain the wider azimuthal extents of SO2 and H2CO compared to CH3OH, where a secondary, gas-phase formation reservoir is required for H2CO.

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