A photometric redshift of z ∼9.4 for GRB 090429B

A. Cucchiara; A. J. Levan; D. B. Fox; N. R. Tanvir; T. N. Ukwatta; E. Berger; T. Krühler; A. Küpcü Yoldaş; X. F. Wu; K. Toma; J. Greiner; F. E. Olivares; A. Rowlinson; L. Amati; T. Sakamoto; K. Roth; A. Stephens; Alexander Fritz; J. P U Fynbo; J. Hjorth; D. Malesani; P. Jakobsson; K. Wiersema; P. T. O'Brien; A. M. Soderberg; R. J. Foley; A. S. Fruchter; J. Rhoads; R. E. Rutledge; B. P. Schmidt; M. A. Dopita; P. Podsiadlowski; R. Willingale; C. Wolf; S. R. Kulkarni; P. D'Avanzo

doi:10.1088/0004-637X/736/1/7

A photometric redshift of z ∼9.4 for GRB 090429B

A. Cucchiara, A. J. Levan, D. B. Fox, N. R. Tanvir, T. N. Ukwatta, E. Berger, T. Krühler, A. Küpcü Yoldaş, X. F. Wu, K. Toma, J. Greiner, F. E. Olivares, A. Rowlinson, L. Amati, T. Sakamoto, K. Roth, A. Stephens, Alexander Fritz, J. P U Fynbo, J. HjorthD. Malesani, P. Jakobsson, K. Wiersema, P. T. O'Brien, A. M. Soderberg, R. J. Foley, A. S. Fruchter, J. Rhoads, R. E. Rutledge, B. P. Schmidt, M. A. Dopita, P. Podsiadlowski, R. Willingale, C. Wolf, S. R. Kulkarni, P. D'Avanzo

Earth and Space Exploration, School of (SESE)

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

379 Scopus citations

Abstract

Gamma-ray bursts (GRBs) serve as powerful probes of the early universe, with their luminous afterglows revealing the locations and physical properties of star-forming galaxies at the highest redshifts, and potentially locating first-generation (Population III) stars. Since GRB afterglows have intrinsically very simple spectra, they allow robust redshifts from low signal-to-noise spectroscopy, or photometry. Here we present a photometric redshift of z ∼9.4 for the Swift detected GRB090429B based on deep observations with Gemini-North, the Very Large Telescope, and the GRB Optical and Near-infrared Detector. Assuming a Small Magellanic Cloud dust law (which has been found in a majority of GRB sight lines), the 90% likelihood range for the redshift is 9.06 < z < 9.52, although there is a low-probability tail toward somewhat lower redshifts. Adopting Milky Way or Large Magellanic Cloud dust laws leads to very similar conclusions, while a Maiolino law does allow somewhat lower redshift solutions, though in all cases the most likely redshift is found to be z > 7. The non-detection of the host galaxy to deep limits (Y(AB) ∼28, which would correspond roughly to 0.001L* at z = 1) in our late-time optical and infrared observations with the Hubble Space Telescope strongly supports the extreme-redshift origin of GRB090429B, since we would expect to have detected any low-z galaxy, even if it were highly dusty. Finally, the energetics of GRB 090429B are comparable to those of other GRBs and suggest that its progenitor is not greatly different from those of lower redshift bursts.

Original language	English (US)
Article number	7
Journal	Astrophysical Journal
Volume	736
Issue number	1
DOIs	https://doi.org/10.1088/0004-637X/736/1/7
State	Published - Jul 20 2011

Keywords

early universe
galaxies: high-redshift
gamma-ray burst: individual (GRB 090429R)
techniques: photometric

ASJC Scopus subject areas

Astronomy and Astrophysics
Space and Planetary Science

Access to Document

10.1088/0004-637X/736/1/7

Cite this

Cucchiara, A., Levan, A. J., Fox, D. B., Tanvir, N. R., Ukwatta, T. N., Berger, E., Krühler, T., Yoldaş, A. K., Wu, X. F., Toma, K., Greiner, J., Olivares, F. E., Rowlinson, A., Amati, L., Sakamoto, T., Roth, K., Stephens, A., Fritz, A., Fynbo, J. P. U., ... D'Avanzo, P. (2011). A photometric redshift of z ∼9.4 for GRB 090429B. Astrophysical Journal, 736(1), Article 7. https://doi.org/10.1088/0004-637X/736/1/7

Cucchiara, A, Levan, AJ, Fox, DB, Tanvir, NR, Ukwatta, TN, Berger, E, Krühler, T, Yoldaş, AK, Wu, XF, Toma, K, Greiner, J, Olivares, FE, Rowlinson, A, Amati, L, Sakamoto, T, Roth, K, Stephens, A, Fritz, A, Fynbo, JPU, Hjorth, J, Malesani, D, Jakobsson, P, Wiersema, K, O'Brien, PT, Soderberg, AM, Foley, RJ, Fruchter, AS, Rhoads, J, Rutledge, RE, Schmidt, BP, Dopita, MA, Podsiadlowski, P, Willingale, R, Wolf, C, Kulkarni, SR & D'Avanzo, P 2011, 'A photometric redshift of z ∼9.4 for GRB 090429B', Astrophysical Journal, vol. 736, no. 1, 7. https://doi.org/10.1088/0004-637X/736/1/7

@article{d235444931494d8bbadff867baf92b9a,

title = "A photometric redshift of z ∼9.4 for GRB 090429B",

abstract = "Gamma-ray bursts (GRBs) serve as powerful probes of the early universe, with their luminous afterglows revealing the locations and physical properties of star-forming galaxies at the highest redshifts, and potentially locating first-generation (Population III) stars. Since GRB afterglows have intrinsically very simple spectra, they allow robust redshifts from low signal-to-noise spectroscopy, or photometry. Here we present a photometric redshift of z ∼9.4 for the Swift detected GRB090429B based on deep observations with Gemini-North, the Very Large Telescope, and the GRB Optical and Near-infrared Detector. Assuming a Small Magellanic Cloud dust law (which has been found in a majority of GRB sight lines), the 90% likelihood range for the redshift is 9.06 < z < 9.52, although there is a low-probability tail toward somewhat lower redshifts. Adopting Milky Way or Large Magellanic Cloud dust laws leads to very similar conclusions, while a Maiolino law does allow somewhat lower redshift solutions, though in all cases the most likely redshift is found to be z > 7. The non-detection of the host galaxy to deep limits (Y(AB) ∼28, which would correspond roughly to 0.001L* at z = 1) in our late-time optical and infrared observations with the Hubble Space Telescope strongly supports the extreme-redshift origin of GRB090429B, since we would expect to have detected any low-z galaxy, even if it were highly dusty. Finally, the energetics of GRB 090429B are comparable to those of other GRBs and suggest that its progenitor is not greatly different from those of lower redshift bursts.",

keywords = "early universe, galaxies: high-redshift, gamma-ray burst: individual (GRB 090429R), techniques: photometric",

author = "A. Cucchiara and Levan, {A. J.} and Fox, {D. B.} and Tanvir, {N. R.} and Ukwatta, {T. N.} and E. Berger and T. Kr{\"u}hler and Yolda{\c s}, {A. K{\"u}pc{\"u}} and Wu, {X. F.} and K. Toma and J. Greiner and Olivares, {F. E.} and A. Rowlinson and L. Amati and T. Sakamoto and K. Roth and A. Stephens and Alexander Fritz and Fynbo, {J. P U} and J. Hjorth and D. Malesani and P. Jakobsson and K. Wiersema and O'Brien, {P. T.} and Soderberg, {A. M.} and Foley, {R. J.} and Fruchter, {A. S.} and J. Rhoads and Rutledge, {R. E.} and Schmidt, {B. P.} and Dopita, {M. A.} and P. Podsiadlowski and R. Willingale and C. Wolf and Kulkarni, {S. R.} and P. D'Avanzo",

year = "2011",

month = jul,

day = "20",

doi = "10.1088/0004-637X/736/1/7",

language = "English (US)",

volume = "736",

journal = "Astrophysical Journal",

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T1 - A photometric redshift of z ∼9.4 for GRB 090429B

AU - Cucchiara, A.

AU - Levan, A. J.

AU - Fox, D. B.

AU - Tanvir, N. R.

AU - Ukwatta, T. N.

AU - Berger, E.

AU - Krühler, T.

AU - Yoldaş, A. Küpcü

AU - Wu, X. F.

AU - Toma, K.

AU - Greiner, J.

AU - Olivares, F. E.

AU - Rowlinson, A.

AU - Amati, L.

AU - Sakamoto, T.

AU - Roth, K.

AU - Stephens, A.

AU - Fritz, Alexander

AU - Fynbo, J. P U

AU - Hjorth, J.

AU - Malesani, D.

AU - Jakobsson, P.

AU - Wiersema, K.

AU - O'Brien, P. T.

AU - Soderberg, A. M.

AU - Foley, R. J.

AU - Fruchter, A. S.

AU - Rhoads, J.

AU - Rutledge, R. E.

AU - Schmidt, B. P.

AU - Dopita, M. A.

AU - Podsiadlowski, P.

AU - Willingale, R.

AU - Wolf, C.

AU - Kulkarni, S. R.

AU - D'Avanzo, P.

PY - 2011/7/20

Y1 - 2011/7/20

N2 - Gamma-ray bursts (GRBs) serve as powerful probes of the early universe, with their luminous afterglows revealing the locations and physical properties of star-forming galaxies at the highest redshifts, and potentially locating first-generation (Population III) stars. Since GRB afterglows have intrinsically very simple spectra, they allow robust redshifts from low signal-to-noise spectroscopy, or photometry. Here we present a photometric redshift of z ∼9.4 for the Swift detected GRB090429B based on deep observations with Gemini-North, the Very Large Telescope, and the GRB Optical and Near-infrared Detector. Assuming a Small Magellanic Cloud dust law (which has been found in a majority of GRB sight lines), the 90% likelihood range for the redshift is 9.06 < z < 9.52, although there is a low-probability tail toward somewhat lower redshifts. Adopting Milky Way or Large Magellanic Cloud dust laws leads to very similar conclusions, while a Maiolino law does allow somewhat lower redshift solutions, though in all cases the most likely redshift is found to be z > 7. The non-detection of the host galaxy to deep limits (Y(AB) ∼28, which would correspond roughly to 0.001L* at z = 1) in our late-time optical and infrared observations with the Hubble Space Telescope strongly supports the extreme-redshift origin of GRB090429B, since we would expect to have detected any low-z galaxy, even if it were highly dusty. Finally, the energetics of GRB 090429B are comparable to those of other GRBs and suggest that its progenitor is not greatly different from those of lower redshift bursts.

AB - Gamma-ray bursts (GRBs) serve as powerful probes of the early universe, with their luminous afterglows revealing the locations and physical properties of star-forming galaxies at the highest redshifts, and potentially locating first-generation (Population III) stars. Since GRB afterglows have intrinsically very simple spectra, they allow robust redshifts from low signal-to-noise spectroscopy, or photometry. Here we present a photometric redshift of z ∼9.4 for the Swift detected GRB090429B based on deep observations with Gemini-North, the Very Large Telescope, and the GRB Optical and Near-infrared Detector. Assuming a Small Magellanic Cloud dust law (which has been found in a majority of GRB sight lines), the 90% likelihood range for the redshift is 9.06 < z < 9.52, although there is a low-probability tail toward somewhat lower redshifts. Adopting Milky Way or Large Magellanic Cloud dust laws leads to very similar conclusions, while a Maiolino law does allow somewhat lower redshift solutions, though in all cases the most likely redshift is found to be z > 7. The non-detection of the host galaxy to deep limits (Y(AB) ∼28, which would correspond roughly to 0.001L* at z = 1) in our late-time optical and infrared observations with the Hubble Space Telescope strongly supports the extreme-redshift origin of GRB090429B, since we would expect to have detected any low-z galaxy, even if it were highly dusty. Finally, the energetics of GRB 090429B are comparable to those of other GRBs and suggest that its progenitor is not greatly different from those of lower redshift bursts.

KW - early universe

KW - galaxies: high-redshift

KW - gamma-ray burst: individual (GRB 090429R)

KW - techniques: photometric

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U2 - 10.1088/0004-637X/736/1/7

DO - 10.1088/0004-637X/736/1/7

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SN - 0004-637X

VL - 736

JO - Astrophysical Journal

JF - Astrophysical Journal

IS - 1

M1 - 7

ER -

A photometric redshift of z ∼9.4 for GRB 090429B

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