A single low-energy, iron-poor supernova as the source of metals in the star SMSS J031300.36−670839.3

The element abundance ratios of four low-mass stars with extremely low metallicities (abundances of elements heavier than helium) indicate that the gas out of which the stars formed was enriched in each case by at most a few—and potentially only one—low-energy supernova. Such supernovae yield large quantities of light elements such as carbon but very little iron. The dominance of low-energy supernovae seems surprising, because it had been expected that the first stars were extremely massive, and that they disintegrated in pair-instability explosions that would rapidly enrich galaxies in iron. What has remained unclear is the yield of iron from the first supernovae, because hitherto no star has been unambiguously interpreted as encapsulating the yield of a single supernova. Here we report the optical spectrum of SMSS J031300.36−670839.3, which shows no evidence of iron (with an upper limit of 10−7.1 times solar abundance). Based on a comparison of its abundance pattern with those of models, we conclude that the star was seeded with material from a single supernova with an original mass about 60 times that of the Sun (and that the supernova left behind a black hole). Taken together with the four previously mentioned low-metallicity stars, we conclude that low-energy supernovae were common in the early Universe, and that such supernovae yielded light-element enrichment with insignificant iron. Reduced stellar feedback both chemically and mechanically from low-energy supernovae would have enabled first-generation stars to form over an extended period. We speculate that such stars may perhaps have had an important role in the epoch of cosmic reionization and the chemical evolution of early galaxies.

[1]  Takeo Minezaki,et al.  Nucleosynthetic signatures of the first stars , 2005, Nature.

[2]  Z. Magic,et al.  The Stagger-grid: A grid of 3D stellar atmosphere models - I. Methods and general properties , 2013, 1302.2621.

[3]  S. E. Woosley,et al.  The Nucleosynthetic Signature of Population III , 2002 .

[4]  J. Dunlop,et al.  NEW CONSTRAINTS ON COSMIC REIONIZATION FROM THE 2012 HUBBLE ULTRA DEEP FIELD CAMPAIGN , 2013, 1301.1228.

[5]  N. Christlieb,et al.  A stellar relic from the early Milky Way , 2002, Nature.

[6]  R. L. Kurucz,et al.  New Grids of ATLAS9 Model Atmospheres , 2004, astro-ph/0405087.

[7]  M. Asplund,et al.  Departures from LTE for neutral Li in late-type stars , 2009, 0906.0899.

[8]  Jonathan R Goodman,et al.  Ensemble samplers with affine invariance , 2010 .

[9]  Nozomu Tominaga,et al.  The Connection between Gamma-Ray Bursts and Extremely Metal-poor Stars: Black Hole-forming Supernovae with Relativistic Jets , 2007, astro-ph/0702471.

[10]  A. Cameron,et al.  The evolution of hydrogen-helium stars , 1971 .

[11]  Vanessa Hill,et al.  An extremely primitive star in the Galactic halo , 2011, Nature.

[12]  T. Greif,et al.  The First Stars , 2003, astro-ph/0311019.

[13]  M. Asplund,et al.  THE MOST METAL-POOR STARS. IV. THE TWO POPULATIONS WITH [Fe/H] ≲ −3.0 , 2012, 1211.3157.

[14]  Hideyuki Umeda,et al.  First-generation black-hole-forming supernovae and the metal abundance pattern of a very iron-poor star , 2003, Nature.

[15]  U. Munari,et al.  EQUIVALENT WIDTH OF NNA I AND K I LINES AND REDDENING , 1997 .

[16]  M. Bessell Measuring the Balmer Jump and the Effective Gravity in FGK Stars , 2007, 0706.2739.

[17]  T. Beers,et al.  THE MOST METAL-POOR STARS. III. THE METALLICITY DISTRIBUTION FUNCTION AND CARBON-ENHANCED METAL-POOR FRACTION,, , 2012, 1208.3016.

[18]  C. Chiappini,et al.  Effects of rotation on the evolution of primordial stars , 2008, 0807.0573.

[19]  P. Seitzer,et al.  The Two Micron All Sky Survey , 1994 .

[20]  F. Hartwick The chemical evolution of the galactic halo , 1976 .

[21]  G. Chiaki,et al.  ONE HUNDRED FIRST STARS: PROTOSTELLAR EVOLUTION AND THE FINAL MASSES , 2013, 1308.4456.

[22]  M. Asplund,et al.  The Stagger-grid: A Grid of 3D Stellar Atmosphere Models V. Fe line shapes, shifts and asymmetries ⋆ , 2013, 1310.4996.

[23]  Stephen A. Shectman,et al.  MIKE: A Double Echelle Spectrograph for the Magellan Telescopes at Las Campanas Observatory , 2003, SPIE Astronomical Telescopes + Instrumentation.

[24]  M. Saimpert,et al.  STANDARD BIG BANG NUCLEOSYNTHESIS UP TO CNO WITH AN IMPROVED EXTENDED NUCLEAR NETWORK , 2011, 1107.1117.

[25]  E. Rollinde,et al.  CHEMICAL CONSTRAINTS ON THE CONTRIBUTION OF POPULATION III STARS TO COSMIC REIONIZATION , 2013, 1310.0684.

[26]  Cnrs,et al.  An extremely primitive halo star , 2012, 1203.2612.

[27]  H. Schatz,et al.  Break-out reactions from the CNO cycles , 1999 .

[28]  S. C. Keller,et al.  The SkyMapper Telescope and The Southern Sky Survey , 2007, Publications of the Astronomical Society of Australia.

[29]  Gabe Bloxham,et al.  The Wide Field Spectrograph (WiFeS): performance and data reduction , 2010, 1002.4472.

[30]  S. Woosley,et al.  MIXING IN ZERO- AND SOLAR-METALLICITY SUPERNOVAE , 2008, 0810.5142.

[31]  Daniel Foreman-Mackey,et al.  emcee: The MCMC Hammer , 2012, 1202.3665.

[32]  T. Beers,et al.  THE MOST METAL-POOR STARS. II. CHEMICAL ABUNDANCES OF 190 METAL-POOR STARS INCLUDING 10 NEW STARS WITH [Fe/H] ⩽ −3.5,, , 2012, 1208.3003.

[33]  J. Bland-Hawthorn,et al.  Pregalactic metal enrichment: The chemical signatures of the first stars , 2011, 1101.4024.

[34]  M. Asplund,et al.  The chemical composition of the Sun , 2009, 0909.0948.

[35]  G. B. Tiepolo New Grids of ATLAS 9 Model Atmospheres , 2004 .

[36]  Kjell Eriksson,et al.  A grid of MARCS model atmospheres for late-type stars. I. Methods and general properties , 2008, 0805.0554.