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Autori principali: Leung, Gene C. K., Eilers, Anna-Christina, Panagiotou, Christos, Wolf, Julien, De, Kishalay, Weisenbach, Luke, Yue, Minghao, Fan, Xiaohui, Ishikawa, Yuzo, Kara, Erin, Krumpe, Mirko, Merloni, Andrea, Simcoe, Robert A., Wang, Feige, Yang, Jinyi
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2605.00978
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author Leung, Gene C. K.
Eilers, Anna-Christina
Panagiotou, Christos
Wolf, Julien
De, Kishalay
Weisenbach, Luke
Yue, Minghao
Fan, Xiaohui
Ishikawa, Yuzo
Kara, Erin
Krumpe, Mirko
Merloni, Andrea
Simcoe, Robert A.
Wang, Feige
Yang, Jinyi
author_facet Leung, Gene C. K.
Eilers, Anna-Christina
Panagiotou, Christos
Wolf, Julien
De, Kishalay
Weisenbach, Luke
Yue, Minghao
Fan, Xiaohui
Ishikawa, Yuzo
Kara, Erin
Krumpe, Mirko
Merloni, Andrea
Simcoe, Robert A.
Wang, Feige
Yang, Jinyi
contents In the nearby universe, quasars are well known to exhibit variability in their brightness over time, offering a powerful tool to probe the physics of accretion onto the SMBH and directly measure the mass of the SMBH. However, detecting variability in early quasars remains challenging. Here, we report the detection of multi-wavelength infrared and X-ray variability in a quasar observed just 850 million years after the Big Bang. The infrared variability spans five filters, tracing rest-frame ultraviolet and optical emission from the accretion disk, while the X-ray variability probes the corona. The variable spectrum reveals that the accretion disk has a geometrically thin, optically thick structure. This provides observational constraints on the accretion disk structure at early times, when quasars are accreting at high Eddington ratios and reside in extreme environments. Our findings demonstrate the feasibility of characterizing accretion physics using variability in the early universe, laying the groundwork for studies exploiting upcoming facilities such as the Rubin Observatory and Roman Space Telescope. These facilities will discover large samples of variable high-redshift quasars, enabling population-level variability studies of accretion physics and black hole masses, filling key missing ingredients in understanding early SMBH growth.
format Preprint
id arxiv_https___arxiv_org_abs_2605_00978
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Discovery of Quasar Variability and Early Accretion Disk Signatures at Cosmic Dawn
Leung, Gene C. K.
Eilers, Anna-Christina
Panagiotou, Christos
Wolf, Julien
De, Kishalay
Weisenbach, Luke
Yue, Minghao
Fan, Xiaohui
Ishikawa, Yuzo
Kara, Erin
Krumpe, Mirko
Merloni, Andrea
Simcoe, Robert A.
Wang, Feige
Yang, Jinyi
Astrophysics of Galaxies
High Energy Astrophysical Phenomena
In the nearby universe, quasars are well known to exhibit variability in their brightness over time, offering a powerful tool to probe the physics of accretion onto the SMBH and directly measure the mass of the SMBH. However, detecting variability in early quasars remains challenging. Here, we report the detection of multi-wavelength infrared and X-ray variability in a quasar observed just 850 million years after the Big Bang. The infrared variability spans five filters, tracing rest-frame ultraviolet and optical emission from the accretion disk, while the X-ray variability probes the corona. The variable spectrum reveals that the accretion disk has a geometrically thin, optically thick structure. This provides observational constraints on the accretion disk structure at early times, when quasars are accreting at high Eddington ratios and reside in extreme environments. Our findings demonstrate the feasibility of characterizing accretion physics using variability in the early universe, laying the groundwork for studies exploiting upcoming facilities such as the Rubin Observatory and Roman Space Telescope. These facilities will discover large samples of variable high-redshift quasars, enabling population-level variability studies of accretion physics and black hole masses, filling key missing ingredients in understanding early SMBH growth.
title Discovery of Quasar Variability and Early Accretion Disk Signatures at Cosmic Dawn
topic Astrophysics of Galaxies
High Energy Astrophysical Phenomena
url https://arxiv.org/abs/2605.00978