Intense star formation within resolved compact regions in a galaxy at z = 2.3

A. M. Swinbank; I. Smail; S. Longmore; A. I. Harris; A. J. Baker; C. De Breuck; J. Richard; A. C. Edge; R. J. Ivison; R. Blundell; K. E.K. Coppin; P. Cox; M. Gurwell; L. J. Hainline; M. Krips; A. Lundgren; R. Neri; B. Siana; G. Siringo; D. P. Stark; D. Wilner; J. D. Younger

doi:10.1038/nature08880

Intense star formation within resolved compact regions in a galaxy at z = 2.3

A. M. Swinbank, I. Smail, S. Longmore, A. I. Harris, A. J. Baker, C. De Breuck, J. Richard, A. C. Edge, R. J. Ivison, R. Blundell, K. E.K. Coppin, P. Cox, M. Gurwell, L. J. Hainline, M. Krips, A. Lundgren, R. Neri, B. Siana, G. Siringo, D. P. StarkD. Wilner, J. D. Younger

School of Arts and Sciences, New High Energy Theory Center

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298 Scopus citations

Abstract

Massive galaxies in the early Universe have been shown to be forming stars at surprisingly high rates. Prominent examples are dust-obscured galaxies which are luminous when observed at sub-millimetre wavelengths and which may be forming stars at a rate of 1,000 solar masses (M) per year. These intense bursts of star formation are believed to be driven by mergers between gas-rich galaxies. Probing the properties of individual star-forming regions within these galaxies, however, is beyond the spatial resolution and sensitivity of even the largest telescopes at present. Here we report observations of the sub-millimetre galaxy SMMJ2135-0102 at redshift z = 2.3259, which has been gravitationally magnified by a factor of 32 by a massive foreground galaxy cluster lens. This magnification, when combined with high-resolution sub-millimetre imaging, resolves the star-forming regions at a linear scale of only 100 parsecs. We find that the luminosity densities of these star-forming regions are comparable to the dense cores of giant molecular clouds in the local Universe, but they are about a hundred times larger and 10 7 times more luminous. Although vigorously star-forming, the underlying physics of the star-formation processes at z 2 appears to be similar to that seen in local galaxies, although the energetics are unlike anything found in the present-day Universe.

Original language	English (US)
Pages (from-to)	733-736
Number of pages	4
Journal	Nature
Volume	464
Issue number	7289
DOIs	https://doi.org/10.1038/nature08880
State	Published - Apr 1 2010

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Swinbank, A. M., Smail, I., Longmore, S., Harris, A. I., Baker, A. J., De Breuck, C., Richard, J., Edge, A. C., Ivison, R. J., Blundell, R., Coppin, K. E. K., Cox, P., Gurwell, M., Hainline, L. J., Krips, M., Lundgren, A., Neri, R., Siana, B., Siringo, G., ... Younger, J. D. (2010). Intense star formation within resolved compact regions in a galaxy at z = 2.3. Nature, 464(7289), 733-736. https://doi.org/10.1038/nature08880

@article{07ed421ea4784576a00d9cd16117009f,

title = "Intense star formation within resolved compact regions in a galaxy at z = 2.3",

abstract = "Massive galaxies in the early Universe have been shown to be forming stars at surprisingly high rates. Prominent examples are dust-obscured galaxies which are luminous when observed at sub-millimetre wavelengths and which may be forming stars at a rate of 1,000 solar masses (M) per year. These intense bursts of star formation are believed to be driven by mergers between gas-rich galaxies. Probing the properties of individual star-forming regions within these galaxies, however, is beyond the spatial resolution and sensitivity of even the largest telescopes at present. Here we report observations of the sub-millimetre galaxy SMMJ2135-0102 at redshift z = 2.3259, which has been gravitationally magnified by a factor of 32 by a massive foreground galaxy cluster lens. This magnification, when combined with high-resolution sub-millimetre imaging, resolves the star-forming regions at a linear scale of only 100 parsecs. We find that the luminosity densities of these star-forming regions are comparable to the dense cores of giant molecular clouds in the local Universe, but they are about a hundred times larger and 10 7 times more luminous. Although vigorously star-forming, the underlying physics of the star-formation processes at z 2 appears to be similar to that seen in local galaxies, although the energetics are unlike anything found in the present-day Universe.",

author = "Swinbank, {A. M.} and I. Smail and S. Longmore and Harris, {A. I.} and Baker, {A. J.} and {De Breuck}, C. and J. Richard and Edge, {A. C.} and Ivison, {R. J.} and R. Blundell and Coppin, {K. E.K.} and P. Cox and M. Gurwell and Hainline, {L. J.} and M. Krips and A. Lundgren and R. Neri and B. Siana and G. Siringo and Stark, {D. P.} and D. Wilner and Younger, {J. D.}",

note = "Funding Information: Acknowledgements We thank the staff at Green Bank Telescope for scheduling the Zpectrometer observations at short notice, and the ESO director for granting director{\textquoteright}s discretionary time observations with SABOCA. A.M.S. gratefully acknowledges a Royal Astronomical Society Sir Norman Lockyer Fellowship, and J.R. and D.P.S. acknowledge a Marie Curie fellowship and a Science Technology and Facilities Council fellowship respectively. J.D.Y. acknowledges support from NASA through a Hubble Fellowship. The Zpectrometer observations were carried out on the Robert C. Byrd Green Bank Telescope, which is operated by the National Radio Astronomy Observatory, a facility of the National Science Foundation operated under cooperative agreement by Associated Universities, Inc. The APEX observations were carried out with ESO Telescopes. The 870 mm interferometric observations were carried out with the Sub-Millimeter Array, which is a joint project between the Smithsonian Astrophysical Observatory and the Academia Sinica Institute of Astronomy and Astrophysics and is funded by the Smithsonian Institution and the Academia Sinica. The CO(3-2) observations were carried out with the Plateau de Bure Interferometer, which is supported by INSU/CNRS (France), Max Planck Gesellschaft (MPG; Germany), and Instituto Geogr{\'a}fico Nacional (IGN; Spain). J. D. Y. is a Hubble Fellow.",

year = "2010",

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day = "1",

doi = "10.1038/nature08880",

language = "English (US)",

volume = "464",

pages = "733--736",

journal = "Nature",

issn = "0028-0836",

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Swinbank, AM, Smail, I, Longmore, S, Harris, AI, Baker, AJ, De Breuck, C, Richard, J, Edge, AC, Ivison, RJ, Blundell, R, Coppin, KEK, Cox, P, Gurwell, M, Hainline, LJ, Krips, M, Lundgren, A, Neri, R, Siana, B, Siringo, G, Stark, DP, Wilner, D & Younger, JD 2010, 'Intense star formation within resolved compact regions in a galaxy at z = 2.3', Nature, vol. 464, no. 7289, pp. 733-736. https://doi.org/10.1038/nature08880

TY - JOUR

T1 - Intense star formation within resolved compact regions in a galaxy at z = 2.3

AU - Swinbank, A. M.

AU - Smail, I.

AU - Longmore, S.

AU - Harris, A. I.

AU - Baker, A. J.

AU - De Breuck, C.

AU - Richard, J.

AU - Edge, A. C.

AU - Ivison, R. J.

AU - Blundell, R.

AU - Coppin, K. E.K.

AU - Cox, P.

AU - Gurwell, M.

AU - Hainline, L. J.

AU - Krips, M.

AU - Lundgren, A.

AU - Neri, R.

AU - Siana, B.

AU - Siringo, G.

AU - Stark, D. P.

AU - Wilner, D.

AU - Younger, J. D.

N1 - Funding Information: Acknowledgements We thank the staff at Green Bank Telescope for scheduling the Zpectrometer observations at short notice, and the ESO director for granting director’s discretionary time observations with SABOCA. A.M.S. gratefully acknowledges a Royal Astronomical Society Sir Norman Lockyer Fellowship, and J.R. and D.P.S. acknowledge a Marie Curie fellowship and a Science Technology and Facilities Council fellowship respectively. J.D.Y. acknowledges support from NASA through a Hubble Fellowship. The Zpectrometer observations were carried out on the Robert C. Byrd Green Bank Telescope, which is operated by the National Radio Astronomy Observatory, a facility of the National Science Foundation operated under cooperative agreement by Associated Universities, Inc. The APEX observations were carried out with ESO Telescopes. The 870 mm interferometric observations were carried out with the Sub-Millimeter Array, which is a joint project between the Smithsonian Astrophysical Observatory and the Academia Sinica Institute of Astronomy and Astrophysics and is funded by the Smithsonian Institution and the Academia Sinica. The CO(3-2) observations were carried out with the Plateau de Bure Interferometer, which is supported by INSU/CNRS (France), Max Planck Gesellschaft (MPG; Germany), and Instituto Geográfico Nacional (IGN; Spain). J. D. Y. is a Hubble Fellow.

PY - 2010/4/1

Y1 - 2010/4/1

N2 - Massive galaxies in the early Universe have been shown to be forming stars at surprisingly high rates. Prominent examples are dust-obscured galaxies which are luminous when observed at sub-millimetre wavelengths and which may be forming stars at a rate of 1,000 solar masses (M) per year. These intense bursts of star formation are believed to be driven by mergers between gas-rich galaxies. Probing the properties of individual star-forming regions within these galaxies, however, is beyond the spatial resolution and sensitivity of even the largest telescopes at present. Here we report observations of the sub-millimetre galaxy SMMJ2135-0102 at redshift z = 2.3259, which has been gravitationally magnified by a factor of 32 by a massive foreground galaxy cluster lens. This magnification, when combined with high-resolution sub-millimetre imaging, resolves the star-forming regions at a linear scale of only 100 parsecs. We find that the luminosity densities of these star-forming regions are comparable to the dense cores of giant molecular clouds in the local Universe, but they are about a hundred times larger and 10 7 times more luminous. Although vigorously star-forming, the underlying physics of the star-formation processes at z 2 appears to be similar to that seen in local galaxies, although the energetics are unlike anything found in the present-day Universe.

AB - Massive galaxies in the early Universe have been shown to be forming stars at surprisingly high rates. Prominent examples are dust-obscured galaxies which are luminous when observed at sub-millimetre wavelengths and which may be forming stars at a rate of 1,000 solar masses (M) per year. These intense bursts of star formation are believed to be driven by mergers between gas-rich galaxies. Probing the properties of individual star-forming regions within these galaxies, however, is beyond the spatial resolution and sensitivity of even the largest telescopes at present. Here we report observations of the sub-millimetre galaxy SMMJ2135-0102 at redshift z = 2.3259, which has been gravitationally magnified by a factor of 32 by a massive foreground galaxy cluster lens. This magnification, when combined with high-resolution sub-millimetre imaging, resolves the star-forming regions at a linear scale of only 100 parsecs. We find that the luminosity densities of these star-forming regions are comparable to the dense cores of giant molecular clouds in the local Universe, but they are about a hundred times larger and 10 7 times more luminous. Although vigorously star-forming, the underlying physics of the star-formation processes at z 2 appears to be similar to that seen in local galaxies, although the energetics are unlike anything found in the present-day Universe.

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U2 - 10.1038/nature08880

DO - 10.1038/nature08880

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SN - 0028-0836

VL - 464

SP - 733

EP - 736

JO - Nature

JF - Nature

IS - 7289

ER -

Intense star formation within resolved compact regions in a galaxy at z = 2.3

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