Modelling the chemical enrichment of Population III supernovae: The
origin of the metals in near-pristine gas clouds
L. Welsh, R. Cooke, und M. Fumagalli. (2019)cite arxiv:1906.00009Comment: 15 pages, 6 figures, Accepted for publication in Monthly Notices of the Royal Astronomical Society.
DOI: 10.1093/mnras/stz1526
Zusammenfassung
The most metal-poor, high redshift damped Lyman-alpha systems (DLAs) provide
a window to study some of the first few generations of stars. In this paper, we
present a novel model to investigate the chemical enrichment of the
near-pristine DLA population. This model accounts for the mass distribution of
the enriching stellar population, the typical explosion energy of their
supernovae, and the average number of stars that contribute to the enrichment
of these DLAs. We conduct a maximum likelihood analysis of these model
parameters using the observed relative element abundances (C/O, Si/O, and
Fe/O) of the 11 most metal-poor DLAs currently known. We find that the mass
distribution of the stars that have enriched this sample of metal-poor DLAs can
be well-described by a Salpeter-like IMF slope at M > 10 M_sun and that a
typical metal-poor DLA has been enriched by < 72 massive stars (95%
confidence), with masses < 40 M_sun. The inferred typical explosion energy
(E_exp = 1.8^+0.3_-0.2x10^51 erg) is somewhat lower than that found by
recent works that model the enrichment of metal-poor halo stars. These
constraints suggest that some of the metal-poor DLAs in our sample may have
been enriched by Population II stars. Using our enrichment model, we also infer
some of the typical physical properties of the most metal-poor DLAs. We
estimate that the total stellar mass content is log10(M_*/M_sun) =
3.5^+0.3_-0.4 and the total gas mass is log10(M_gas/M_sun) =
7.0^+0.3_-0.4 for systems with a relative oxygen abundance O/H ~ -3.0.
Beschreibung
Modelling the chemical enrichment of Population III supernovae: The origin of the metals in near-pristine gas clouds
%0 Generic
%1 welsh2019modelling
%A Welsh, Louise
%A Cooke, Ryan
%A Fumagalli, Michele
%D 2019
%K library
%R 10.1093/mnras/stz1526
%T Modelling the chemical enrichment of Population III supernovae: The
origin of the metals in near-pristine gas clouds
%U http://arxiv.org/abs/1906.00009
%X The most metal-poor, high redshift damped Lyman-alpha systems (DLAs) provide
a window to study some of the first few generations of stars. In this paper, we
present a novel model to investigate the chemical enrichment of the
near-pristine DLA population. This model accounts for the mass distribution of
the enriching stellar population, the typical explosion energy of their
supernovae, and the average number of stars that contribute to the enrichment
of these DLAs. We conduct a maximum likelihood analysis of these model
parameters using the observed relative element abundances (C/O, Si/O, and
Fe/O) of the 11 most metal-poor DLAs currently known. We find that the mass
distribution of the stars that have enriched this sample of metal-poor DLAs can
be well-described by a Salpeter-like IMF slope at M > 10 M_sun and that a
typical metal-poor DLA has been enriched by < 72 massive stars (95%
confidence), with masses < 40 M_sun. The inferred typical explosion energy
(E_exp = 1.8^+0.3_-0.2x10^51 erg) is somewhat lower than that found by
recent works that model the enrichment of metal-poor halo stars. These
constraints suggest that some of the metal-poor DLAs in our sample may have
been enriched by Population II stars. Using our enrichment model, we also infer
some of the typical physical properties of the most metal-poor DLAs. We
estimate that the total stellar mass content is log10(M_*/M_sun) =
3.5^+0.3_-0.4 and the total gas mass is log10(M_gas/M_sun) =
7.0^+0.3_-0.4 for systems with a relative oxygen abundance O/H ~ -3.0.
@misc{welsh2019modelling,
abstract = {The most metal-poor, high redshift damped Lyman-alpha systems (DLAs) provide
a window to study some of the first few generations of stars. In this paper, we
present a novel model to investigate the chemical enrichment of the
near-pristine DLA population. This model accounts for the mass distribution of
the enriching stellar population, the typical explosion energy of their
supernovae, and the average number of stars that contribute to the enrichment
of these DLAs. We conduct a maximum likelihood analysis of these model
parameters using the observed relative element abundances ([C/O], [Si/O], and
[Fe/O]) of the 11 most metal-poor DLAs currently known. We find that the mass
distribution of the stars that have enriched this sample of metal-poor DLAs can
be well-described by a Salpeter-like IMF slope at M > 10 M_sun and that a
typical metal-poor DLA has been enriched by < 72 massive stars (95%
confidence), with masses < 40 M_sun. The inferred typical explosion energy
(E_exp = 1.8^{+0.3}_{-0.2}x10^51 erg) is somewhat lower than that found by
recent works that model the enrichment of metal-poor halo stars. These
constraints suggest that some of the metal-poor DLAs in our sample may have
been enriched by Population II stars. Using our enrichment model, we also infer
some of the typical physical properties of the most metal-poor DLAs. We
estimate that the total stellar mass content is log10(M_*/M_sun) =
3.5^{+0.3}_{-0.4} and the total gas mass is log10(M_gas/M_sun) =
7.0^{+0.3}_{-0.4} for systems with a relative oxygen abundance [O/H] ~ -3.0.},
added-at = {2019-06-04T03:44:15.000+0200},
author = {Welsh, Louise and Cooke, Ryan and Fumagalli, Michele},
biburl = {https://www.bibsonomy.org/bibtex/2dd78b8a598515dcb2e857f0eed261bda/gpkulkarni},
description = {Modelling the chemical enrichment of Population III supernovae: The origin of the metals in near-pristine gas clouds},
doi = {10.1093/mnras/stz1526},
interhash = {7de5c5b94f6b83f15925561b76b83ec9},
intrahash = {dd78b8a598515dcb2e857f0eed261bda},
keywords = {library},
note = {cite arxiv:1906.00009Comment: 15 pages, 6 figures, Accepted for publication in Monthly Notices of the Royal Astronomical Society},
timestamp = {2019-06-04T03:44:15.000+0200},
title = {Modelling the chemical enrichment of Population III supernovae: The
origin of the metals in near-pristine gas clouds},
url = {http://arxiv.org/abs/1906.00009},
year = 2019
}