Primordial rotating disk composed of at least 15 dense star-forming clumps at cosmic dawn

S. Fujimoto; M. Ouchi; K. Kohno; F. Valentino; C. Giménez-Arteaga; G. B. Brammer; L. J. Furtak; M. Kohandel; M. Oguri; A. Pallottini; J. Richard; A. Zitrin; F. E. Bauer; M. Boylan-Kolchin; M. Dessauges-Zavadsky; E. Egami; S. L. Finkelstein; Z. Ma; I. Smail; D. Watson; T. A. Hutchison; J. R. Rigby; B. D. Welch; Y. Ao; L. D. Bradley; G. B. Caminha; K. I. Caputi; D. Espada; R. Endsley; Y. Fudamoto; J. González-López; B. Hatsukade; A. M. Koekemoer; V. Kokorev; N. Laporte; M. Lee; G. E. Magdis; Y. Ono; F. Rizzo; T. Shibuya; K. Shimasaku; F. Sun; S. Toft; H. Umehata; T. Wang; H. Yajima

doi:10.1038/s41550-025-02592-w

Primordial rotating disk composed of at least 15 dense star-forming clumps at cosmic dawn

S. Fujimoto
, M. Ouchi
, K. Kohno
, F. Valentino
, C. Giménez-Arteaga
, G. B. Brammer
, L. J. Furtak
, M. Kohandel
, M. Oguri
, A. Pallottini
, J. Richard
, A. Zitrin
, F. E. Bauer
, M. Boylan-Kolchin
, M. Dessauges-Zavadsky
, E. Egami
, S. L. Finkelstein
, Z. Ma
, I. Smail
, D. Watson

T. A. Hutchison, J. R. Rigby, B. D. Welch, Y. Ao, L. D. Bradley, G. B. Caminha, K. I. Caputi, D. Espada, R. Endsley, Y. Fudamoto, J. González-López, B. Hatsukade, A. M. Koekemoer, V. Kokorev, N. Laporte, M. Lee, G. E. Magdis, Y. Ono, F. Rizzo, T. Shibuya, K. Shimasaku, F. Sun, S. Toft, H. Umehata, T. Wang, H. Yajima

Steward Observatory

Research output: Contribution to journal › Article › peer-review

9 Scopus citations

Abstract

Early galaxies form through dark matter and gas assembly, evolving into dynamically hot, chaotic structures driven by mergers and feedback. By contrast, remarkably smooth, rotating disks are observed in massive galaxies only 1.4 billion years after the Big Bang, implying rapid dynamical evolution. Probing this evolution mechanism necessitates studies of young galaxies, yet efforts have been hindered by observational limitations in both sensitivity and spatial resolution. Here we report high-resolution observations of a strongly lensed, quintuply imaged, low-luminosity young galaxy at redshift z = 6.072, just 930 million years after the Big Bang. Magnified by gravitational lensing, the galaxy resolves into at least 15 star-forming clumps (effective radii ~10–60 pc), dominating ~70% of the galaxy’s ultraviolet flux. Cool gas emission reveals an underlying rotating disk (rotational-to-random motion ratio 3.58 ± 0.74) in a gravitationally unstable state (Toomre Q ≈ 0.2–0.3) with high surface gas densities comparable to local starbursts (~10³⁻⁵ M_⊙ pc⁻²). These properties suggest that disk instabilities with weak feedback drive prolific clump formation. The extreme clumpiness surpasses galaxies at later epochs and current simulation predictions. Our findings directly connect small-scale internal structures, underlying disk dynamics along with feedback effects at cosmic dawn, potentially explaining the abundance of luminous galaxies observed in the early Universe.

Original language	English (US)
Pages (from-to)	1553-1567
Number of pages	15
Journal	Nature Astronomy
Volume	9
Issue number	10
DOIs	https://doi.org/10.1038/s41550-025-02592-w
State	Published - Oct 2025

ASJC Scopus subject areas

Astronomy and Astrophysics

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10.1038/s41550-025-02592-w

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Fujimoto, S., Ouchi, M., Kohno, K., Valentino, F., Giménez-Arteaga, C., Brammer, G. B., Furtak, L. J., Kohandel, M., Oguri, M., Pallottini, A., Richard, J., Zitrin, A., Bauer, F. E., Boylan-Kolchin, M., Dessauges-Zavadsky, M., Egami, E., Finkelstein, S. L., Ma, Z., Smail, I., ... Yajima, H. (2025). Primordial rotating disk composed of at least 15 dense star-forming clumps at cosmic dawn. Nature Astronomy, 9(10), 1553-1567. https://doi.org/10.1038/s41550-025-02592-w

Fujimoto, S, Ouchi, M, Kohno, K, Valentino, F, Giménez-Arteaga, C, Brammer, GB, Furtak, LJ, Kohandel, M, Oguri, M, Pallottini, A, Richard, J, Zitrin, A, Bauer, FE, Boylan-Kolchin, M, Dessauges-Zavadsky, M, Egami, E, Finkelstein, SL, Ma, Z, Smail, I, Watson, D, Hutchison, TA, Rigby, JR, Welch, BD, Ao, Y, Bradley, LD, Caminha, GB, Caputi, KI, Espada, D, Endsley, R, Fudamoto, Y, González-López, J, Hatsukade, B, Koekemoer, AM, Kokorev, V, Laporte, N, Lee, M, Magdis, GE, Ono, Y, Rizzo, F, Shibuya, T, Shimasaku, K, Sun, F, Toft, S, Umehata, H, Wang, T & Yajima, H 2025, 'Primordial rotating disk composed of at least 15 dense star-forming clumps at cosmic dawn', Nature Astronomy, vol. 9, no. 10, pp. 1553-1567. https://doi.org/10.1038/s41550-025-02592-w

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title = "Primordial rotating disk composed of at least 15 dense star-forming clumps at cosmic dawn",

abstract = "Early galaxies form through dark matter and gas assembly, evolving into dynamically hot, chaotic structures driven by mergers and feedback. By contrast, remarkably smooth, rotating disks are observed in massive galaxies only 1.4 billion years after the Big Bang, implying rapid dynamical evolution. Probing this evolution mechanism necessitates studies of young galaxies, yet efforts have been hindered by observational limitations in both sensitivity and spatial resolution. Here we report high-resolution observations of a strongly lensed, quintuply imaged, low-luminosity young galaxy at redshift z = 6.072, just 930 million years after the Big Bang. Magnified by gravitational lensing, the galaxy resolves into at least 15 star-forming clumps (effective radii \textasciitilde{}10–60 pc), dominating \textasciitilde{}70\% of the galaxy{\textquoteright}s ultraviolet flux. Cool gas emission reveals an underlying rotating disk (rotational-to-random motion ratio 3.58 ± 0.74) in a gravitationally unstable state (Toomre Q ≈ 0.2–0.3) with high surface gas densities comparable to local starbursts (\textasciitilde{}103−5 M⊙ pc−2). These properties suggest that disk instabilities with weak feedback drive prolific clump formation. The extreme clumpiness surpasses galaxies at later epochs and current simulation predictions. Our findings directly connect small-scale internal structures, underlying disk dynamics along with feedback effects at cosmic dawn, potentially explaining the abundance of luminous galaxies observed in the early Universe.",

author = "S. Fujimoto and M. Ouchi and K. Kohno and F. Valentino and C. Gim{\'e}nez-Arteaga and Brammer, \{G. B.\} and Furtak, \{L. J.\} and M. Kohandel and M. Oguri and A. Pallottini and J. Richard and A. Zitrin and Bauer, \{F. E.\} and M. Boylan-Kolchin and M. Dessauges-Zavadsky and E. Egami and Finkelstein, \{S. L.\} and Z. Ma and I. Smail and D. Watson and Hutchison, \{T. A.\} and Rigby, \{J. R.\} and Welch, \{B. D.\} and Y. Ao and Bradley, \{L. D.\} and Caminha, \{G. B.\} and Caputi, \{K. I.\} and D. Espada and R. Endsley and Y. Fudamoto and J. Gonz{\'a}lez-L{\'o}pez and B. Hatsukade and Koekemoer, \{A. M.\} and V. Kokorev and N. Laporte and M. Lee and Magdis, \{G. E.\} and Y. Ono and F. Rizzo and T. Shibuya and K. Shimasaku and F. Sun and S. Toft and H. Umehata and T. Wang and H. Yajima",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to Springer Nature Limited 2025.",

year = "2025",

month = oct,

doi = "10.1038/s41550-025-02592-w",

language = "English (US)",

volume = "9",

pages = "1553--1567",

journal = "Nature Astronomy",

issn = "2397-3366",

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TY - JOUR

T1 - Primordial rotating disk composed of at least 15 dense star-forming clumps at cosmic dawn

AU - Fujimoto, S.

AU - Ouchi, M.

AU - Kohno, K.

AU - Valentino, F.

AU - Giménez-Arteaga, C.

AU - Brammer, G. B.

AU - Furtak, L. J.

AU - Kohandel, M.

AU - Oguri, M.

AU - Pallottini, A.

AU - Richard, J.

AU - Zitrin, A.

AU - Bauer, F. E.

AU - Boylan-Kolchin, M.

AU - Dessauges-Zavadsky, M.

AU - Egami, E.

AU - Finkelstein, S. L.

AU - Ma, Z.

AU - Smail, I.

AU - Watson, D.

AU - Hutchison, T. A.

AU - Rigby, J. R.

AU - Welch, B. D.

AU - Ao, Y.

AU - Bradley, L. D.

AU - Caminha, G. B.

AU - Caputi, K. I.

AU - Espada, D.

AU - Endsley, R.

AU - Fudamoto, Y.

AU - González-López, J.

AU - Hatsukade, B.

AU - Koekemoer, A. M.

AU - Kokorev, V.

AU - Laporte, N.

AU - Lee, M.

AU - Magdis, G. E.

AU - Ono, Y.

AU - Rizzo, F.

AU - Shibuya, T.

AU - Shimasaku, K.

AU - Sun, F.

AU - Toft, S.

AU - Umehata, H.

AU - Wang, T.

AU - Yajima, H.

PY - 2025/10

Y1 - 2025/10

N2 - Early galaxies form through dark matter and gas assembly, evolving into dynamically hot, chaotic structures driven by mergers and feedback. By contrast, remarkably smooth, rotating disks are observed in massive galaxies only 1.4 billion years after the Big Bang, implying rapid dynamical evolution. Probing this evolution mechanism necessitates studies of young galaxies, yet efforts have been hindered by observational limitations in both sensitivity and spatial resolution. Here we report high-resolution observations of a strongly lensed, quintuply imaged, low-luminosity young galaxy at redshift z = 6.072, just 930 million years after the Big Bang. Magnified by gravitational lensing, the galaxy resolves into at least 15 star-forming clumps (effective radii ~10–60 pc), dominating ~70% of the galaxy’s ultraviolet flux. Cool gas emission reveals an underlying rotating disk (rotational-to-random motion ratio 3.58 ± 0.74) in a gravitationally unstable state (Toomre Q ≈ 0.2–0.3) with high surface gas densities comparable to local starbursts (~103−5 M⊙ pc−2). These properties suggest that disk instabilities with weak feedback drive prolific clump formation. The extreme clumpiness surpasses galaxies at later epochs and current simulation predictions. Our findings directly connect small-scale internal structures, underlying disk dynamics along with feedback effects at cosmic dawn, potentially explaining the abundance of luminous galaxies observed in the early Universe.

AB - Early galaxies form through dark matter and gas assembly, evolving into dynamically hot, chaotic structures driven by mergers and feedback. By contrast, remarkably smooth, rotating disks are observed in massive galaxies only 1.4 billion years after the Big Bang, implying rapid dynamical evolution. Probing this evolution mechanism necessitates studies of young galaxies, yet efforts have been hindered by observational limitations in both sensitivity and spatial resolution. Here we report high-resolution observations of a strongly lensed, quintuply imaged, low-luminosity young galaxy at redshift z = 6.072, just 930 million years after the Big Bang. Magnified by gravitational lensing, the galaxy resolves into at least 15 star-forming clumps (effective radii ~10–60 pc), dominating ~70% of the galaxy’s ultraviolet flux. Cool gas emission reveals an underlying rotating disk (rotational-to-random motion ratio 3.58 ± 0.74) in a gravitationally unstable state (Toomre Q ≈ 0.2–0.3) with high surface gas densities comparable to local starbursts (~103−5 M⊙ pc−2). These properties suggest that disk instabilities with weak feedback drive prolific clump formation. The extreme clumpiness surpasses galaxies at later epochs and current simulation predictions. Our findings directly connect small-scale internal structures, underlying disk dynamics along with feedback effects at cosmic dawn, potentially explaining the abundance of luminous galaxies observed in the early Universe.

UR - https://www.scopus.com/pages/publications/105012881952

UR - https://www.scopus.com/pages/publications/105012881952#tab=citedBy

U2 - 10.1038/s41550-025-02592-w

DO - 10.1038/s41550-025-02592-w

M3 - Article

AN - SCOPUS:105012881952

SN - 2397-3366

VL - 9

SP - 1553

EP - 1567

JO - Nature Astronomy

JF - Nature Astronomy

IS - 10

ER -

Primordial rotating disk composed of at least 15 dense star-forming clumps at cosmic dawn

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