Grant, Sierra L. and van Dishoeck, Ewine F. and Tabone, Benoît and Gasman, Danny and Henning, Thomas and Kamp, Inga and Güdel, Manuel and Lagage, Pierre-Olivier and Bettoni, Giulio and Perotti, Giulia and Christiaens, Valentin and Samland, Matthias and Arabhavi, Aditya M. and Argyriou, Ioannis and Abergel, Alain and Absil, Olivier and Barrado, David and Boccaletti, Anthony and Bouwman, Jeroen and o Garatti, Alessio Caratti and Geers, Vincent and Glauser, Adrian M. and Guadarrama, Rodrigo and Jang, Hyerin and Kanwar, Jayatee and Lahuis, Fred and Morales-Calderón, Maria and Mueller, Michael and Nehmé, Cyrine and Olofsson, Göran and Pantin, Eric and Pawellek, Nicole and Ray, Tom P. and Rodgers-Lee, Donna and Scheithauer, Silvia and Schreiber, Jürgen and Schwarz, Kamber and Temmink, Milou and Vandenbussche, Bart and Vlasblom, Marissa and Waters, L. B. F. M. and Wright, Gillian and Colina, Luis and Greve, Thomas R. and Justannont, Kay and Östlin, Göran (2023) MINDS. The Detection of 13 CO 2 with JWST-MIRI Indicates Abundant CO 2 in a Protoplanetary Disk. The Astrophysical Journal Letters, 947 (1). L6. ISSN 2041-8205
1.pdf - Published Version
Download (2MB)
Abstract
We present JWST-MIRI Medium Resolution Spectrometer (MRS) spectra of the protoplanetary disk around the low-mass T Tauri star GW Lup from the MIRI mid-INfrared Disk Survey Guaranteed Time Observations program. Emission from 12CO2, 13CO2, H2O, HCN, C2H2, and OH is identified with 13CO2 being detected for the first time in a protoplanetary disk. We characterize the chemical and physical conditions in the inner few astronomical units of the GW Lup disk using these molecules as probes. The spectral resolution of JWST-MIRI MRS paired with high signal-to-noise data is essential to identify these species and determine their column densities and temperatures. The Q branches of these molecules, including those of hot bands, are particularly sensitive to temperature and column density. We find that the 12CO2 emission in the GW Lup disk is coming from optically thick emission at a temperature of ∼400 K. 13CO2 is optically thinner and based on a lower temperature of ∼325 K, and thus may be tracing deeper into the disk and/or a larger emitting radius than 12CO2. The derived ${N}_{{\mathrm{CO}}_{2}}$/${N}_{{{\rm{H}}}_{2}{\rm{O}}}$ ratio is orders of magnitude higher than previously derived for GW Lup and other targets based on Spitzer-InfraRed-Spectrograph data. This high column density ratio may be due to an inner cavity with a radius in between the H2O and CO2 snowlines and/or an overall lower disk temperature. This paper demonstrates the unique ability of JWST to probe inner disk structures and chemistry through weak, previously unseen molecular features.
Item Type: | Article |
---|---|
Subjects: | GO for STM > Physics and Astronomy |
Depositing User: | Unnamed user with email support@goforstm.com |
Date Deposited: | 19 Apr 2023 07:07 |
Last Modified: | 30 Jan 2024 06:20 |
URI: | http://archive.article4submit.com/id/eprint/585 |