Silicate emission in a type-2 quasar: JWST/MIRI constraints on torus geometry and radiative feedback
Silicate emission in a type-2 quasar: JWST/MIRI constraints on torus geometry and radiative feedback
Type-2 quasars (QSO2s) are AGN seen through a significant amount of dust and gas that obscures the central supermassive black hole and the broad line region. Despite this, recent mid-infrared spectra of the central 0.5-1.1 kpc of five QSO2s at z~0.1, obtained with the MRS module of JWST/MIRI, revealed 9.7, 18, and 23 micron silicate features in emission in two of them. This indicates that the high angular resolution of JWST/MIRI now allows us to peer into their nuclear region, exposing some of the directly illuminated dusty clouds that produce silicate emission. To test this, we fitted the nuclear mid-infrared spectrum of the QSO2 with the strongest silicate features, J1010, with two different sets of torus models implemented in an updated version of the Bayesian tool {\tt BayesClumpy}. These are the CLUMPY and the CAT3D-WIND models. The CAT3D-WIND model is preferred by the observations based on the marginal likelihood and fit residuals, although the two torus models successfully reproduce the spectrum by means of intermediate covering factors ($\rm C_T=0.45\pm^{0.26}_{0.18}$ and $\rm C_T=0.66\pm^{0.16}_{0.17}$ for the CLUMPY and CAT3D-WIND models) and low inclinations ($\rm i=50^\circ\pm^{8^\circ}_{9^\circ}$ and $\rm i=13^\circ\pm^{7^\circ}_{6^\circ}$). Indeed, four of the five QSO2s with JWST/MIRI observations, including J1010, are in the blowout or ''forbidden'' region of the Eddington ratio-column density diagram, indicating that they are actively clearing gas and dust from their nuclear regions, leading to reduced covering factors. This is in contrast with Seyfert 2 galaxies observed with JWST, which are in the ''permitted'' regions of the diagram and show 9.7 micron silicate features in absorption. This supports a scenario where the more luminous the AGN and the higher their Eddington ratio, the lower the torus covering factor, driven by radiation pressure on dusty gas.
astro-ph.GA
Almeida, C. Ramos
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Ramos, A. Asensio
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Plaza, C. Westerdorp
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García-Bernete, I.
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Lopez-Rodriguez, E.
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Hönig, S.
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Audibert, A.
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García-Burillo, S.
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Pereira-Santaella, M.
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Donnan, F.
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Alonso-Herrero, A.
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González-Martín, O.
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Levenson, N.
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Rigopoulou, D.
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Tadhunter, C.
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Speranza, G.
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February 2026
Almeida, C. Ramos
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Ramos, A. Asensio
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Plaza, C. Westerdorp
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García-Bernete, I.
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Lopez-Rodriguez, E.
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Hönig, S.
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Audibert, A.
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García-Burillo, S.
56a7c385-47c0-4550-ba26-f939f36d071a
Pereira-Santaella, M.
273d2fb4-ea55-4bd1-9031-37bf7a2cda75
Donnan, F.
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Alonso-Herrero, A.
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González-Martín, O.
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Levenson, N.
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Rigopoulou, D.
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Tadhunter, C.
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Speranza, G.
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Almeida, C. Ramos, Ramos, A. Asensio, Plaza, C. Westerdorp, García-Bernete, I., Lopez-Rodriguez, E., Hönig, S., Audibert, A., García-Burillo, S., Pereira-Santaella, M., Donnan, F., Alonso-Herrero, A., González-Martín, O., Levenson, N., Rigopoulou, D., Tadhunter, C. and Speranza, G.
(2026)
Silicate emission in a type-2 quasar: JWST/MIRI constraints on torus geometry and radiative feedback.
Astronomy & Astrophysics, 706, [A100].
(doi:10.1051/0004-6361/202557323).
Abstract
Type-2 quasars (QSO2s) are AGN seen through a significant amount of dust and gas that obscures the central supermassive black hole and the broad line region. Despite this, recent mid-infrared spectra of the central 0.5-1.1 kpc of five QSO2s at z~0.1, obtained with the MRS module of JWST/MIRI, revealed 9.7, 18, and 23 micron silicate features in emission in two of them. This indicates that the high angular resolution of JWST/MIRI now allows us to peer into their nuclear region, exposing some of the directly illuminated dusty clouds that produce silicate emission. To test this, we fitted the nuclear mid-infrared spectrum of the QSO2 with the strongest silicate features, J1010, with two different sets of torus models implemented in an updated version of the Bayesian tool {\tt BayesClumpy}. These are the CLUMPY and the CAT3D-WIND models. The CAT3D-WIND model is preferred by the observations based on the marginal likelihood and fit residuals, although the two torus models successfully reproduce the spectrum by means of intermediate covering factors ($\rm C_T=0.45\pm^{0.26}_{0.18}$ and $\rm C_T=0.66\pm^{0.16}_{0.17}$ for the CLUMPY and CAT3D-WIND models) and low inclinations ($\rm i=50^\circ\pm^{8^\circ}_{9^\circ}$ and $\rm i=13^\circ\pm^{7^\circ}_{6^\circ}$). Indeed, four of the five QSO2s with JWST/MIRI observations, including J1010, are in the blowout or ''forbidden'' region of the Eddington ratio-column density diagram, indicating that they are actively clearing gas and dust from their nuclear regions, leading to reduced covering factors. This is in contrast with Seyfert 2 galaxies observed with JWST, which are in the ''permitted'' regions of the diagram and show 9.7 micron silicate features in absorption. This supports a scenario where the more luminous the AGN and the higher their Eddington ratio, the lower the torus covering factor, driven by radiation pressure on dusty gas.
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2512.02629v1
- Author's Original
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aa57323-25
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Accepted/In Press date: 2 December 2025
e-pub ahead of print date: 3 February 2026
Published date: February 2026
Keywords:
astro-ph.GA
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Local EPrints ID: 511812
URI: http://eprints.soton.ac.uk/id/eprint/511812
ISSN: 0004-6361
PURE UUID: ab92757e-1a7a-46ab-9023-b0e87e1681f1
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Date deposited: 03 Jun 2026 16:47
Last modified: 03 Jun 2026 16:47
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Contributors
Author:
C. Ramos Almeida
Author:
A. Asensio Ramos
Author:
C. Westerdorp Plaza
Author:
I. García-Bernete
Author:
E. Lopez-Rodriguez
Author:
A. Audibert
Author:
S. García-Burillo
Author:
M. Pereira-Santaella
Author:
F. Donnan
Author:
A. Alonso-Herrero
Author:
O. González-Martín
Author:
N. Levenson
Author:
D. Rigopoulou
Author:
C. Tadhunter
Author:
G. Speranza
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