The JWST/MIRI view of the planetary nebula NGC 6302 - I. A UV-irradiated torus and a hot bubble triggering PAH formation

Matsuura, Mikako ORCID: https://orcid.org/0000-0002-5529-5593, Volk, Kevin, Kavanagh, Patrick, Balick, Bruce, Wesson, Roger, Zijlstra, Albert A., Dinerstein, Harriet L., Peeters, Els, Sterling, N. C., Cami, Jan, Barlow, M. J., Kastner, Joel, Walsh, Jeremy R., Waters, L. B. F. M., Hirano, Naomi, Aleman, Isabel, Bernard-Salas, Jeronimo, Bhatt, Charmi, Blommaert, Joris, Clark, Nicholas, Jones, Olivia, Justtanont, Kay, Kemper, F., Kraemer, Kathleen E., Lagadec, Eric, Laming, J. Martin, Molster, F. J., Moraga Baez, Paula, Monteiro, H., Richards, Anita M. S., Sahai, Raghvendra, Sloan, G. C., Torki, Maryam, van Hoof, Peter A. M., Wright, Nicholas J., Wilson, Finnbar and Csukai, Alexander 2025. The JWST/MIRI view of the planetary nebula NGC 6302 - I. A UV-irradiated torus and a hot bubble triggering PAH formation. Monthly Notices of the Royal Astronomical Society 542 (2) , pp. 1287-1307. 10.1093/mnras/staf1194

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Abstract

NGC 6302 is a spectacular bipolar planetary nebula (PN) whose spectrum exhibitsfast outflows and highly ionized emission lines, indicating the presence of a very hot central star (∼220 000 K). Its infrared spectrum reveals a mixed oxygen and carbon dust chemistry, displaying both silicate and polycyclic aromatic hydrocarbon (PAH) features. Using the James Webb Space Telescope Mid-Infrared Instrument and Medium Resolution Spectrometer, a mosaic map was obtained over the core of NGC 6302, covering the wavelength range of 5–28 μm and spanning an area of ∼18.5 arcsec × 15arcsec. The spatially resolved spectrum reveals ∼200 molecular and ionized lines from species requiring ionization potentials of up to 205 eV. The spatial distributions highlight a complex structure at the nebula’s centre. Highly ionized species such as [Mg VII] and [Si VII] show compact structures, while lower ionization species such as H+ extend much farther outwards, forming filament-defined rims that delineate a bubble. Within the bubble, the H+ and H2 emission coincide, while the PAH emission appears farther out, indicating an ionization structure distinct from typical photodissociation regions, such as the Orion Bar. This may be the first identification of a PAH formation site in a PN. This PN appears to be shaped not by a steady, continuous outflow, but by a series of dynamic, impulsive bubble ejections, creating local conditions conducive to PAH formation. A dusty torus surrounds the core, primarily composed of large (μm-sized) silicate grains with crystalline components. The long-lived torus contains a substantial mass of material, which could support an equilibrium chemistry and a slow dust-formation process.

Item Type:	Article
Date Type:	Publication
Status:	Published
Schools:	Schools > Physics and Astronomy
Publisher:	Oxford University Press
ISSN:	0035-8711
Funders:	STFC
Date of First Compliant Deposit:	28 August 2025
Date of Acceptance:	16 July 2025
Last Modified:	29 Aug 2025 13:45
URI:	https://orca.cardiff.ac.uk/id/eprint/180716

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