Galaxy growth in a massive halo in the first billion years of cosmic history

D. P. Marrone; J. S. Spilker; C. C. Hayward; J. D. Vieira; M. Aravena; M. L.N. Ashby; M. B. Bayliss; M. Béthermin; M. Brodwin; M. S. Bothwell; J. E. Carlstrom; S. C. Chapman; Chian Chou Chen; T. M. Crawford; D. J.M. Cunningham; C. De Breuck; C. D. Fassnacht; A. H. Gonzalez; T. R. Greve; Y. D. Hezaveh; K. Lacaille; K. C. Litke; S. Lower; J. Ma; M. Malkan; T. B. Miller; W. R. Morningstar; E. J. Murphy; D. Narayanan; K. A. Phadke; K. M. Rotermund; J. Sreevani; B. Stalder; A. A. Stark; M. L. Strandet; M. Tang; A. Weiß

doi:10.1038/nature24629

Galaxy growth in a massive halo in the first billion years of cosmic history

D. P. Marrone, J. S. Spilker, C. C. Hayward, J. D. Vieira, M. Aravena, M. L.N. Ashby, M. B. Bayliss, M. Béthermin, M. Brodwin, M. S. Bothwell, J. E. Carlstrom, S. C. Chapman, Chian Chou Chen, T. M. Crawford, D. J.M. Cunningham, C. De Breuck, C. D. Fassnacht, A. H. Gonzalez, T. R. Greve, Y. D. HezavehK. Lacaille, K. C. Litke, S. Lower, J. Ma, M. Malkan, T. B. Miller, W. R. Morningstar, E. J. Murphy, D. Narayanan, K. A. Phadke, K. M. Rotermund, J. Sreevani, B. Stalder, A. A. Stark, M. L. Strandet, M. Tang, A. Weiß

Astronomy

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Abstract

According to the current understanding of cosmic structure formation, the precursors of the most massive structures in the Universe began to form shortly after the Big Bang, in regions corresponding to the largest fluctuations in the cosmic density field. Observing these structures during their period of active growth and assembly - the first few hundred million years of the Universe - is challenging because it requires surveys that are sensitive enough to detect the distant galaxies that act as signposts for these structures and wide enough to capture the rarest objects. As a result, very few such objects have been detected so far. Here we report observations of a far-infrared-luminous object at redshift 6.900 (less than 800 million years after the Big Bang) that was discovered in a wide-field survey. High-resolution imaging shows it to be a pair of extremely massive star-forming galaxies. The larger is forming stars at a rate of 2,900 solar masses per year, contains 270 billion solar masses of gas and 2.5 billion solar masses of dust, and is more massive than any other known object at a redshift of more than 6. Its rapid star formation is probably triggered by its companion galaxy at a projected separation of 8 kiloparsecs. This merging companion hosts 35 billion solar masses of stars and has a star-formation rate of 540 solar masses per year, but has an order of magnitude less gas and dust than its neighbour and physical conditions akin to those observed in lower-metallicity galaxies in the nearby Universe. These objects suggest the presence of a dark-matter halo with a mass of more than 100 billion solar masses, making it among the rarest dark-matter haloes that should exist in the Universe at this epoch.

Original language	English (US)
Pages (from-to)	51-54
Number of pages	4
Journal	Nature
Volume	553
Issue number	7686
DOIs	https://doi.org/10.1038/nature24629
State	Published - Jan 4 2018

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Marrone, D. P., Spilker, J. S., Hayward, C. C., Vieira, J. D., Aravena, M., Ashby, M. L. N., Bayliss, M. B., Béthermin, M., Brodwin, M., Bothwell, M. S., Carlstrom, J. E., Chapman, S. C., Chen, C. C., Crawford, T. M., Cunningham, D. J. M., De Breuck, C., Fassnacht, C. D., Gonzalez, A. H., Greve, T. R., ... Weiß, A. (2018). Galaxy growth in a massive halo in the first billion years of cosmic history. Nature, 553(7686), 51-54. https://doi.org/10.1038/nature24629

Marrone, DP, Spilker, JS, Hayward, CC, Vieira, JD, Aravena, M, Ashby, MLN, Bayliss, MB, Béthermin, M, Brodwin, M, Bothwell, MS, Carlstrom, JE, Chapman, SC, Chen, CC, Crawford, TM, Cunningham, DJM, De Breuck, C, Fassnacht, CD, Gonzalez, AH, Greve, TR, Hezaveh, YD, Lacaille, K, Litke, KC, Lower, S, Ma, J, Malkan, M, Miller, TB, Morningstar, WR, Murphy, EJ, Narayanan, D, Phadke, KA, Rotermund, KM, Sreevani, J, Stalder, B, Stark, AA, Strandet, ML, Tang, M & Weiß, A 2018, 'Galaxy growth in a massive halo in the first billion years of cosmic history', Nature, vol. 553, no. 7686, pp. 51-54. https://doi.org/10.1038/nature24629

@article{7a8bee55afb7428a93597a4ed4561338,

title = "Galaxy growth in a massive halo in the first billion years of cosmic history",

abstract = "According to the current understanding of cosmic structure formation, the precursors of the most massive structures in the Universe began to form shortly after the Big Bang, in regions corresponding to the largest fluctuations in the cosmic density field. Observing these structures during their period of active growth and assembly - the first few hundred million years of the Universe - is challenging because it requires surveys that are sensitive enough to detect the distant galaxies that act as signposts for these structures and wide enough to capture the rarest objects. As a result, very few such objects have been detected so far. Here we report observations of a far-infrared-luminous object at redshift 6.900 (less than 800 million years after the Big Bang) that was discovered in a wide-field survey. High-resolution imaging shows it to be a pair of extremely massive star-forming galaxies. The larger is forming stars at a rate of 2,900 solar masses per year, contains 270 billion solar masses of gas and 2.5 billion solar masses of dust, and is more massive than any other known object at a redshift of more than 6. Its rapid star formation is probably triggered by its companion galaxy at a projected separation of 8 kiloparsecs. This merging companion hosts 35 billion solar masses of stars and has a star-formation rate of 540 solar masses per year, but has an order of magnitude less gas and dust than its neighbour and physical conditions akin to those observed in lower-metallicity galaxies in the nearby Universe. These objects suggest the presence of a dark-matter halo with a mass of more than 100 billion solar masses, making it among the rarest dark-matter haloes that should exist in the Universe at this epoch.",

author = "Marrone, {D. P.} and Spilker, {J. S.} and Hayward, {C. C.} and Vieira, {J. D.} and M. Aravena and Ashby, {M. L.N.} and Bayliss, {M. B.} and M. B{\'e}thermin and M. Brodwin and Bothwell, {M. S.} and Carlstrom, {J. E.} and Chapman, {S. C.} and Chen, {Chian Chou} and Crawford, {T. M.} and Cunningham, {D. J.M.} and {De Breuck}, C. and Fassnacht, {C. D.} and Gonzalez, {A. H.} and Greve, {T. R.} and Hezaveh, {Y. D.} and K. Lacaille and Litke, {K. C.} and S. Lower and J. Ma and M. Malkan and Miller, {T. B.} and Morningstar, {W. R.} and Murphy, {E. J.} and D. Narayanan and Phadke, {K. A.} and Rotermund, {K. M.} and J. Sreevani and B. Stalder and Stark, {A. A.} and Strandet, {M. L.} and M. Tang and A. Wei{\ss}",

note = "Funding Information: Acknowledgements ALMA is a partnership of ESO (representing its member states), NSF (USA) and NINS (Japan), together with NRC (Canada) and NSC and ASIAA (Taiwan), in cooperation with the Republic of Chile. The Joint ALMA Observatory is operated by ESO, AUI/NRAO and NAOJ. This work incorporates observations with the NASA/ESA Hubble Space Telescope, obtained at the Space Telescope Science Institute (STScI) operated by AURA. This work is based in part on observations made with the Spitzer Space Telescope, which is operated by the Jet Propulsion Laboratory, California Institute of Technology under a contract with NASA. The SPT is supported by the NSF through grant PLR-1248097, with partial support through PHY-1125897, the Kavli Foundation and the Gordon and Betty Moore Foundation grant GBMF 947. Supporting observations were obtained at the Gemini Observatory, which is operated by the Association of Universities for Research in Astronomy, under a cooperative agreement with the NSF on behalf of the Gemini partnership of NSF (USA), NRC (Canada), CONICYT (Chile), Ministerio de Ciencia, Tecnolog{\'i}a e Innovaci{\'o}n Productiva (Argentina) and Minist{\'e}rio da Ci{\^e}ncia, Tecnologia e Inova{\c c}{\~a}o (Brazil). D.P.M., J.S.S., J.D.V., K.C.L. and J.S. acknowledge support from the US NSF under grant AST-1312950. D.P.M. was partially supported by NASA through grant HST-GO-14740 from the Space Telescope Science Institute. K.C.L. was partially supported by SOSPA4-007 from the National Radio Astronomy Observatory. The Flatiron Institute is supported by the Simons Foundation. J.D.V. acknowledges support from an A. P. Sloan Foundation Fellowship. Y.D.H. is a Hubble fellow. Publisher Copyright: {\textcopyright} 2018 Macmillan Publishers Limited, part of Springer Nature. All rights reserved.",

year = "2018",

month = jan,

day = "4",

doi = "10.1038/nature24629",

language = "English (US)",

volume = "553",

pages = "51--54",

journal = "Nature",

issn = "0028-0836",

publisher = "Nature Publishing Group",

number = "7686",

}

TY - JOUR

T1 - Galaxy growth in a massive halo in the first billion years of cosmic history

AU - Marrone, D. P.

AU - Spilker, J. S.

AU - Hayward, C. C.

AU - Vieira, J. D.

AU - Aravena, M.

AU - Ashby, M. L.N.

AU - Bayliss, M. B.

AU - Béthermin, M.

AU - Brodwin, M.

AU - Bothwell, M. S.

AU - Carlstrom, J. E.

AU - Chapman, S. C.

AU - Chen, Chian Chou

AU - Crawford, T. M.

AU - Cunningham, D. J.M.

AU - De Breuck, C.

AU - Fassnacht, C. D.

AU - Gonzalez, A. H.

AU - Greve, T. R.

AU - Hezaveh, Y. D.

AU - Lacaille, K.

AU - Litke, K. C.

AU - Lower, S.

AU - Ma, J.

AU - Malkan, M.

AU - Miller, T. B.

AU - Morningstar, W. R.

AU - Murphy, E. J.

AU - Narayanan, D.

AU - Phadke, K. A.

AU - Rotermund, K. M.

AU - Sreevani, J.

AU - Stalder, B.

AU - Stark, A. A.

AU - Strandet, M. L.

AU - Tang, M.

AU - Weiß, A.

N1 - Funding Information: Acknowledgements ALMA is a partnership of ESO (representing its member states), NSF (USA) and NINS (Japan), together with NRC (Canada) and NSC and ASIAA (Taiwan), in cooperation with the Republic of Chile. The Joint ALMA Observatory is operated by ESO, AUI/NRAO and NAOJ. This work incorporates observations with the NASA/ESA Hubble Space Telescope, obtained at the Space Telescope Science Institute (STScI) operated by AURA. This work is based in part on observations made with the Spitzer Space Telescope, which is operated by the Jet Propulsion Laboratory, California Institute of Technology under a contract with NASA. The SPT is supported by the NSF through grant PLR-1248097, with partial support through PHY-1125897, the Kavli Foundation and the Gordon and Betty Moore Foundation grant GBMF 947. Supporting observations were obtained at the Gemini Observatory, which is operated by the Association of Universities for Research in Astronomy, under a cooperative agreement with the NSF on behalf of the Gemini partnership of NSF (USA), NRC (Canada), CONICYT (Chile), Ministerio de Ciencia, Tecnología e Innovación Productiva (Argentina) and Ministério da Ciência, Tecnologia e Inovação (Brazil). D.P.M., J.S.S., J.D.V., K.C.L. and J.S. acknowledge support from the US NSF under grant AST-1312950. D.P.M. was partially supported by NASA through grant HST-GO-14740 from the Space Telescope Science Institute. K.C.L. was partially supported by SOSPA4-007 from the National Radio Astronomy Observatory. The Flatiron Institute is supported by the Simons Foundation. J.D.V. acknowledges support from an A. P. Sloan Foundation Fellowship. Y.D.H. is a Hubble fellow. Publisher Copyright: © 2018 Macmillan Publishers Limited, part of Springer Nature. All rights reserved.

PY - 2018/1/4

Y1 - 2018/1/4

N2 - According to the current understanding of cosmic structure formation, the precursors of the most massive structures in the Universe began to form shortly after the Big Bang, in regions corresponding to the largest fluctuations in the cosmic density field. Observing these structures during their period of active growth and assembly - the first few hundred million years of the Universe - is challenging because it requires surveys that are sensitive enough to detect the distant galaxies that act as signposts for these structures and wide enough to capture the rarest objects. As a result, very few such objects have been detected so far. Here we report observations of a far-infrared-luminous object at redshift 6.900 (less than 800 million years after the Big Bang) that was discovered in a wide-field survey. High-resolution imaging shows it to be a pair of extremely massive star-forming galaxies. The larger is forming stars at a rate of 2,900 solar masses per year, contains 270 billion solar masses of gas and 2.5 billion solar masses of dust, and is more massive than any other known object at a redshift of more than 6. Its rapid star formation is probably triggered by its companion galaxy at a projected separation of 8 kiloparsecs. This merging companion hosts 35 billion solar masses of stars and has a star-formation rate of 540 solar masses per year, but has an order of magnitude less gas and dust than its neighbour and physical conditions akin to those observed in lower-metallicity galaxies in the nearby Universe. These objects suggest the presence of a dark-matter halo with a mass of more than 100 billion solar masses, making it among the rarest dark-matter haloes that should exist in the Universe at this epoch.

AB - According to the current understanding of cosmic structure formation, the precursors of the most massive structures in the Universe began to form shortly after the Big Bang, in regions corresponding to the largest fluctuations in the cosmic density field. Observing these structures during their period of active growth and assembly - the first few hundred million years of the Universe - is challenging because it requires surveys that are sensitive enough to detect the distant galaxies that act as signposts for these structures and wide enough to capture the rarest objects. As a result, very few such objects have been detected so far. Here we report observations of a far-infrared-luminous object at redshift 6.900 (less than 800 million years after the Big Bang) that was discovered in a wide-field survey. High-resolution imaging shows it to be a pair of extremely massive star-forming galaxies. The larger is forming stars at a rate of 2,900 solar masses per year, contains 270 billion solar masses of gas and 2.5 billion solar masses of dust, and is more massive than any other known object at a redshift of more than 6. Its rapid star formation is probably triggered by its companion galaxy at a projected separation of 8 kiloparsecs. This merging companion hosts 35 billion solar masses of stars and has a star-formation rate of 540 solar masses per year, but has an order of magnitude less gas and dust than its neighbour and physical conditions akin to those observed in lower-metallicity galaxies in the nearby Universe. These objects suggest the presence of a dark-matter halo with a mass of more than 100 billion solar masses, making it among the rarest dark-matter haloes that should exist in the Universe at this epoch.

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JO - Nature

JF - Nature

IS - 7686

ER -

Galaxy growth in a massive halo in the first billion years of cosmic history

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