Outliers from the mainstream: How a massive star can produce a gamma-ray Burst

S. Campana; N. Panagia; D. Lazzati; A. P. Beardmore; G. Cusumano; O. Godet; G. Chincarini; S. Covino; M. Della Valle; C. Guidorzi; D. Malesani; A. Moretti; R. Perna; P. Romano; G. Tagliaferri

doi:10.1086/592066

Outliers from the mainstream: How a massive star can produce a gamma-ray Burst

S. Campana
, N. Panagia
, D. Lazzati
, A. P. Beardmore
, G. Cusumano
, O. Godet
, G. Chincarini
, S. Covino
, M. Della Valle
, C. Guidorzi
, D. Malesani
, A. Moretti
, R. Perna
, P. Romano
, G. Tagliaferri

Physics and Astronomy

Stony Brook University

Osservatorio Astronomico di Brera
Space Telescope Science Institute
Osservatorio Astrofisico di Catania
Supernova Ltd.
University of Colorado Boulder
University of Leicester
National Institute for Astrophysics
University of Milan - Bicocca
European Southern Observatory
Osservatorio Astronomico di Capodimonte
University of Rome La Sapienza
University of Copenhagen

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

2 Scopus citations

Abstract

It is now recognized that long-duration gamma-ray Bursts (GRBs) are linked to the collapse of massive stars, based on the association between (low redshift) GRBs and (Type Ic) core-collapse supernovae (SNe). The census of massive stars and GRBs reveals, however, that not all massive stars produce a GRB. Only-1% of corecollapse SNe are able to produce a highly relativistic collimated outflow, and hence a GRB. The extra crucial parameter has long been suspected to be metallicity and/or rotation. We find observational evidence strongly supporting that both ingredients are necessary in order to make a GRB out of a core-collapsing star. A detailed study of the absorption pattern in the X-ray spectrum of GRB 060218 reveals evidence of material highly enriched in low-atomic-number metals ejected before the SN/GRB explosion. We find that, within the current scenarios of stellar evolution, only a progenitor star characterized by a fast stellar rotation and subsolar initial metallicity could produce such a metal enrichment in its close surrounding.

Original language	English
Pages (from-to)	L9-L12
Journal	Astrophysical Journal
Volume	684
Issue number	1 PART 2
DOIs	https://doi.org/10.1086/592066
State	Published - 2008

Keywords

Bursts-stars
Color figure
Evolution-stars
Gamma rays
Individual (grb 060218) online material

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10.1086/592066

Cite this

Campana, S., Panagia, N., Lazzati, D., Beardmore, A. P., Cusumano, G., Godet, O., Chincarini, G., Covino, S., Valle, M. D., Guidorzi, C., Malesani, D., Moretti, A., Perna, R., Romano, P., & Tagliaferri, G. (2008). Outliers from the mainstream: How a massive star can produce a gamma-ray Burst. Astrophysical Journal, 684(1 PART 2), L9-L12. https://doi.org/10.1086/592066

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title = "Outliers from the mainstream: How a massive star can produce a gamma-ray Burst",

abstract = "It is now recognized that long-duration gamma-ray Bursts (GRBs) are linked to the collapse of massive stars, based on the association between (low redshift) GRBs and (Type Ic) core-collapse supernovae (SNe). The census of massive stars and GRBs reveals, however, that not all massive stars produce a GRB. Only-1\% of corecollapse SNe are able to produce a highly relativistic collimated outflow, and hence a GRB. The extra crucial parameter has long been suspected to be metallicity and/or rotation. We find observational evidence strongly supporting that both ingredients are necessary in order to make a GRB out of a core-collapsing star. A detailed study of the absorption pattern in the X-ray spectrum of GRB 060218 reveals evidence of material highly enriched in low-atomic-number metals ejected before the SN/GRB explosion. We find that, within the current scenarios of stellar evolution, only a progenitor star characterized by a fast stellar rotation and subsolar initial metallicity could produce such a metal enrichment in its close surrounding.",

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author = "S. Campana and N. Panagia and D. Lazzati and Beardmore, \{A. P.\} and G. Cusumano and O. Godet and G. Chincarini and S. Covino and Valle, \{M. Della\} and C. Guidorzi and D. Malesani and A. Moretti and R. Perna and P. Romano and G. Tagliaferri",

year = "2008",

doi = "10.1086/592066",

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TY - JOUR

T1 - Outliers from the mainstream

T2 - How a massive star can produce a gamma-ray Burst

AU - Campana, S.

AU - Panagia, N.

AU - Lazzati, D.

AU - Beardmore, A. P.

AU - Cusumano, G.

AU - Godet, O.

AU - Chincarini, G.

AU - Covino, S.

AU - Valle, M. Della

AU - Guidorzi, C.

AU - Malesani, D.

AU - Moretti, A.

AU - Perna, R.

AU - Romano, P.

AU - Tagliaferri, G.

PY - 2008

Y1 - 2008

N2 - It is now recognized that long-duration gamma-ray Bursts (GRBs) are linked to the collapse of massive stars, based on the association between (low redshift) GRBs and (Type Ic) core-collapse supernovae (SNe). The census of massive stars and GRBs reveals, however, that not all massive stars produce a GRB. Only-1% of corecollapse SNe are able to produce a highly relativistic collimated outflow, and hence a GRB. The extra crucial parameter has long been suspected to be metallicity and/or rotation. We find observational evidence strongly supporting that both ingredients are necessary in order to make a GRB out of a core-collapsing star. A detailed study of the absorption pattern in the X-ray spectrum of GRB 060218 reveals evidence of material highly enriched in low-atomic-number metals ejected before the SN/GRB explosion. We find that, within the current scenarios of stellar evolution, only a progenitor star characterized by a fast stellar rotation and subsolar initial metallicity could produce such a metal enrichment in its close surrounding.

AB - It is now recognized that long-duration gamma-ray Bursts (GRBs) are linked to the collapse of massive stars, based on the association between (low redshift) GRBs and (Type Ic) core-collapse supernovae (SNe). The census of massive stars and GRBs reveals, however, that not all massive stars produce a GRB. Only-1% of corecollapse SNe are able to produce a highly relativistic collimated outflow, and hence a GRB. The extra crucial parameter has long been suspected to be metallicity and/or rotation. We find observational evidence strongly supporting that both ingredients are necessary in order to make a GRB out of a core-collapsing star. A detailed study of the absorption pattern in the X-ray spectrum of GRB 060218 reveals evidence of material highly enriched in low-atomic-number metals ejected before the SN/GRB explosion. We find that, within the current scenarios of stellar evolution, only a progenitor star characterized by a fast stellar rotation and subsolar initial metallicity could produce such a metal enrichment in its close surrounding.

KW - Bursts-stars

KW - Color figure

KW - Evolution-stars

KW - Gamma rays

KW - Individual (grb 060218) online material

UR - https://www.scopus.com/pages/publications/84902748831

U2 - 10.1086/592066

DO - 10.1086/592066

M3 - Article

SN - 0004-637X

VL - 684

SP - L9-L12

JO - Astrophysical Journal

JF - Astrophysical Journal

IS - 1 PART 2

ER -

Outliers from the mainstream: How a massive star can produce a gamma-ray Burst

Abstract

Keywords

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