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Autores principales: Cloonan, Aidan P., Whitaker, Katherine E., Manning, Sinclaire M., Williams, Christina C., Greene, Jenny E., Oesch, Pascal A., Weibel, Andrea, Brammer, Gabriel, de Graaff, Anna, Hviding, Raphael E., Dayal, Pratika, Jespersen, Christian Kragh, Ji, Zhiyuan, Labbe, Ivo, Xiao, Mengyuan, Zhang, Yunchong
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2603.24700
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author Cloonan, Aidan P.
Whitaker, Katherine E.
Manning, Sinclaire M.
Williams, Christina C.
Greene, Jenny E.
Oesch, Pascal A.
Weibel, Andrea
Brammer, Gabriel
de Graaff, Anna
Hviding, Raphael E.
Dayal, Pratika
Jespersen, Christian Kragh
Ji, Zhiyuan
Labbe, Ivo
Xiao, Mengyuan
Zhang, Yunchong
author_facet Cloonan, Aidan P.
Whitaker, Katherine E.
Manning, Sinclaire M.
Williams, Christina C.
Greene, Jenny E.
Oesch, Pascal A.
Weibel, Andrea
Brammer, Gabriel
de Graaff, Anna
Hviding, Raphael E.
Dayal, Pratika
Jespersen, Christian Kragh
Ji, Zhiyuan
Labbe, Ivo
Xiao, Mengyuan
Zhang, Yunchong
contents Among the most remarkable results from JWST is the discovery of abundant, compact, and very red sources in the early Universe known as "Little Red Dots" (LRDs). The relative degree to which starlight and active galactic nuclei (AGN) drive the rest-frame UV and optical emission from LRDs remains unclear. With a large sample of LRDs selected photometrically from the pure-parallel PANORAMIC survey, we study their morphology as a function of rest-wavelength and find that the rest-UV light is typically more extended than the rest-optical. This result holds both when measuring LRD sizes with a single Sérsic profile and when comparing the fraction of light from a point source via joint PSF+Sérsic modeling. A shift occurs at the Balmer break, with LRDs becoming highly compact and unresolved ($R_{50,\rm{opt}}\lesssim100\;\rm{pc}$) in the rest-optical relative to the rest-UV. When splitting the sample at the Balmer break into those that are resolved and unresolved, a stacking analysis demonstrates that the latter are compact ($R_{50}\lesssim100\;\rm{pc}$) on average across the full rest-UV-optical spectrum. Conversely, those LRDs resolved at the break show extended UV emission ($R_{50,\rm{UV}}>200\;\rm{pc}$) on average. We find a similar dichotomy when repeating with a spectroscopic sample. Altogether, these results are consistent with the rest-UV emission driven by a combination of emission from starlight and a dense, dust-poor cloud of hydrogen gas enveloping an AGN. Differences between LRDs in the relative contribution from the AGN and starlight could reflect an ensemble of black hole seed masses, where a heavier seed produces an LRD of smaller $R_{50,\rm{UV}}$.
format Preprint
id arxiv_https___arxiv_org_abs_2603_24700
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle A PANORAMIC of UV-optical morphologies of "Little Red Dots": Two groups of LRDs distinguished by UV half-light radius
Cloonan, Aidan P.
Whitaker, Katherine E.
Manning, Sinclaire M.
Williams, Christina C.
Greene, Jenny E.
Oesch, Pascal A.
Weibel, Andrea
Brammer, Gabriel
de Graaff, Anna
Hviding, Raphael E.
Dayal, Pratika
Jespersen, Christian Kragh
Ji, Zhiyuan
Labbe, Ivo
Xiao, Mengyuan
Zhang, Yunchong
Astrophysics of Galaxies
Among the most remarkable results from JWST is the discovery of abundant, compact, and very red sources in the early Universe known as "Little Red Dots" (LRDs). The relative degree to which starlight and active galactic nuclei (AGN) drive the rest-frame UV and optical emission from LRDs remains unclear. With a large sample of LRDs selected photometrically from the pure-parallel PANORAMIC survey, we study their morphology as a function of rest-wavelength and find that the rest-UV light is typically more extended than the rest-optical. This result holds both when measuring LRD sizes with a single Sérsic profile and when comparing the fraction of light from a point source via joint PSF+Sérsic modeling. A shift occurs at the Balmer break, with LRDs becoming highly compact and unresolved ($R_{50,\rm{opt}}\lesssim100\;\rm{pc}$) in the rest-optical relative to the rest-UV. When splitting the sample at the Balmer break into those that are resolved and unresolved, a stacking analysis demonstrates that the latter are compact ($R_{50}\lesssim100\;\rm{pc}$) on average across the full rest-UV-optical spectrum. Conversely, those LRDs resolved at the break show extended UV emission ($R_{50,\rm{UV}}>200\;\rm{pc}$) on average. We find a similar dichotomy when repeating with a spectroscopic sample. Altogether, these results are consistent with the rest-UV emission driven by a combination of emission from starlight and a dense, dust-poor cloud of hydrogen gas enveloping an AGN. Differences between LRDs in the relative contribution from the AGN and starlight could reflect an ensemble of black hole seed masses, where a heavier seed produces an LRD of smaller $R_{50,\rm{UV}}$.
title A PANORAMIC of UV-optical morphologies of "Little Red Dots": Two groups of LRDs distinguished by UV half-light radius
topic Astrophysics of Galaxies
url https://arxiv.org/abs/2603.24700