201 research outputs found
Atomic data for S II - Toward Better Diagnostics of Chemical Evolution in High-redshift Galaxies
Absorption-line spectroscopy is a powerful tool used to estimate element
abundances in the nearby as well as distant universe. The accuracy of the
abundances thus derived is, naturally, limited by the accuracy of the atomic
data assumed for the spectral lines. We have recently started a project to
perform the new extensive atomic data calculations used for optical/UV spectral
lines in the plasma modeling code Cloudy using state-of-the-art quantal
calculations. Here we demonstrate our approach by focussing on S II, an ion
used to estimate metallicities for Milky Way interstellar clouds as well as
distant damped Lyman-alpha (DLA) and sub-DLA absorber galaxies detected in the
spectra of quasars and gamma-ray bursts (GRBs). We report new extensive
calculations of a large number of energy levels of S II, and the line strengths
of the resulting radiative transitions. Our calculations are based on the
configuration interaction approach within a numerical Hartree-Fock framework,
and utilize both non-ralativistic and quasirelativistic one-electron radial
orbitals. The results of these new atomic calculations are then incorporated
into Cloudy and applied to a lab plasma, and a typical DLA, for illustrative
purposes. The new results imply relatively modest changes (~0.04 dex) to the
metallicities estimated from S II in past studies. These results will be
readily applicable to other studies of S II in the Milky Way and other
galaxies.Comment: Accepted for publication in The Astrophysical Journal; 34 pages, 10
figure
Atomic data for Zn II - Improving Spectral Diagnostics of Chemical Evolution in High-redshift Galaxies
Damped Lyman-alpha (DLA) and sub-DLA absorbers in quasar spectra provide the
most sensitive tools for measuring element abundances of distant galaxies.
Estimation of abundances from absorption lines depends sensitively on the
accuracy of the atomic data used. We have started a project to produce new
atomic spectroscopic parameters for optical/UV spectral lines using
state-of-the-art computer codes employing very broad configuration interaction
basis. Here we report our results for Zn II, an ion used widely in studies of
the interstellar medium (ISM) as well as DLA/sub-DLAs. We report new
calculations of many energy levels of Zn II, and the line strengths of the
resulting radiative transitions. Our calculations use the configuration
interaction approach within a numerical Hartree-Fock framework. We use both
non-relativistic and quasi-relativistic one-electron radial orbitals. We have
incorporated the results of these atomic calculations into the plasma
simulation code Cloudy, and applied them to a lab plasma and examples of a DLA
and a sub-DLA. Our values of the Zn II {\lambda}{\lambda} 2026, 2062 oscillator
strengths are higher than previous values by 0.10 dex. Cloudy calculations for
representative absorbers with the revised Zn atomic data imply ionization
corrections lower than calculated before by 0.05 dex. The new results imply Zn
metallicities should be lower by 0.1 dex for DLAs and by 0.13-0.15 dex for
sub-DLAs than in past studies. Our results can be applied to other studies of
Zn II in the Galactic and extragalactic ISM.Comment: accepted The Astrophysical Journa
Radiative cooling in collisionally and photo ionized plasmas
We discuss recent improvements in the calculation of the radiative cooling in
both collisionally and photo ionized plasmas. We are extending the spectral
simulation code Cloudy so that as much as possible of the underlying atomic
data is taken from external databases, some created by others, some developed
by the Cloudy team. This paper focuses on recent changes in the treatment of
many stages of ionization of iron, and discusses its extensions to other
elements. The H-like and He-like ions are treated in the iso-electronic
approach described previously. Fe II is a special case treated with a large
model atom. Here we focus on Fe III through Fe XXIV, ions which are important
contributors to the radiative cooling of hot, 1e5 to 1e7 K, plasmas and for
X-ray spectroscopy. We use the Chianti atomic database to greatly expand the
number of transitions in the cooling function. Chianti only includes lines that
have atomic data computed by sophisticated methods. This limits the line list
to lower excitation, longer wavelength, transitions. We had previously included
lines from the Opacity Project database, which tends to include higher energy,
shorter wavelength, transitions. These were combined with various forms of the
g-bar approximation, a highly approximate method of estimating collision rates.
For several iron ions the two databases are almost entirely complementary. We
adopt a hybrid approach in which we use Chianti where possible, supplemented by
lines from the Opacity Project for shorter wavelength transitions. The total
cooling including the lightest thirty elements differs significantly from some
previous calculations
Accurate determination of the free-free Gaunt factor. II - relativistic Gaunt factors
When modelling an ionised plasma, all spectral synthesis codes need the
thermally averaged free-free Gaunt factor defined over a very wide range of
parameter space in order to produce an accurate prediction for the spectrum.
Until now no data set exists that would meet these needs completely. We have
therefore produced a table of relativistic Gaunt factors over a much wider
range of parameter space than has ever been produced before. We present tables
of the thermally averaged Gaunt factor covering the range log10(gamma^2) = -6
to 10 and log10(u) = -16 to 13 for all atomic numbers Z = 1 through 36. The
data were calculated using the relativistic Bethe-Heitler-Elwert (BHE)
approximation and were subsequently merged with accurate non-relativistic
results in those parts of the parameter space where the BHE approximation is
not valid. These data will be incorporated in the next major release of the
spectral synthesis code Cloudy. We also produced tables of the frequency
integrated Gaunt factor covering the parameter space log10(gamma^2) = -6 to 10
for all values of Z between 1 and 36. All the data presented in this paper are
available online.Comment: 8 pages, 8 figures, 2 table
Accurate determination of the free-free Gaunt factor; I - non-relativistic Gaunt factors
Modern spectral synthesis codes need the thermally averaged free-free Gaunt
factor defined over a very wide range of parameter space in order to produce an
accurate prediction for the spectrum emitted by an ionized plasma. Until now no
set of data exists that would meet this need in a fully satisfactory way. We
have therefore undertaken to produce a table of very accurate non-relativistic
Gaunt factors over a much wider range of parameters than has ever been produced
before. We first produced a table of non-averaged Gaunt factors, covering the
parameter space log10(epsilon_i) = -20 to +10 and log10(w) = -30 to +25. We
then continued to produce a table of thermally averaged Gaunt factors covering
the parameter space log10(gamma^2) = -6 to +10 and log10(u) = -16 to +13.
Finally we produced a table of the frequency integrated Gaunt factor covering
the parameter space log10(gamma^2) = -6 to +10. All the data presented in this
paper are available online.Comment: 10 pages, 5 tables, 3 figures. Fixed typo in Eq. 1
Expanded Iron UTA spectra -- probing the thermal stability limits in AGN clouds
The Fe unresolved transition array (UTAs) produce prominent features in the
15-17?A wavelength range in the spectra of Active Galactic Nuclei (AGN). Here
we present new calculations of the energies and oscillator strengths of inner-
shell lines from Fe XIV, Fe XV, and Fe XVI. These are crucial ions since they
are dominant at inflection points in the gas thermal stability curve, and UTA
excitation followed by autoionization is an important ionization mechanism for
these species. We incorporate these, and data reported in previous papers, into
the plasma simulation code Cloudy. This updated physics is subsequently
employed to reconsider the thermally stable phases in absorbing media in Active
Galactic Nuclei. We show how the absorption profile of the Fe XIV UTA depends
on density, due to the changing populations of levels within the ground
configuration.Comment: ApJ in pres
Atomic Data for Zn ɪɪ: Improving Spectral Diagnostics of Chemical Evolution in High-Redshift Galaxies
Damped Lyα (DLA) and sub-DLA absorbers in quasar spectra provide the most sensitive tools for measuring the element abundances of distant galaxies. The estimation of abundances from absorption lines depends sensitively on the accuracy of the atomic data used. We have started a project to produce new atomic spectroscopic parameters for optical and UV spectral lines using state-of-the-art computer codes employing a very broad configuration interaction (CI) basis. Here we report our results for Zn ii, an ion used widely in studies of the interstellar medium (ISM) as well as DLAs and sub-DLAs. We report new calculations of many energy levels of Zn ii and the line strengths of the resulting radiative transitions. Our calculations use the CI approach within a numerical Hartree–Fock framework. We use both nonrelativistic and quasi-relativistic one-electron radial orbitals. We have incorporated the results of these atomic calculations into the plasma simulation code Cloudy and applied them to a lab plasma and examples of a DLA and a sub-DLA. Our values of the Zn ii 2026, 2062 oscillator strengths are higher than previous values by 0.10 dex. The Cloudy calculations for representative absorbers with the revised Zn atomic data imply ionization corrections lower than calculated earlier by 0.05 dex. The new results imply that Zn metallicities should be lower by 0.1 dex for DLAs and by 0.13–0.15 dex for sub-DLAs than in past studies. Our results can be applied to other studies of Zn ii in the Galactic and extragalactic ISM
Radiative Cooling in Collisionally Ionized and Photoionized Plasmas
We discuss recent improvements in the calculation of the radiative cooling in both collisionally ionized and photoionized plasmas. We are extending the spectral simulation code CLOUDY so that as much as possible of the underlying atomic data are taken from external data bases, some created by others and some developed by the CLOUDY team. This paper focuses on recent changes in the treatment of many stages of ionization of iron, and discusses its extensions to other elements. The H- and He-like ions are treated in the isoelectronic approach described previously. Fe II is a special case treated with a large model atom. Here we focus on Fe III through Fe XXIV, ions which are important contributors to the radiative cooling of hot (T ∼ 105–107 K) plasmas and for X-ray spectroscopy. We use the Chianti atomic data base to greatly expand the number of transitions in the cooling function. Chianti only includes lines that have atomic data computed by sophisticated methods. This limits the line list to lower excitation, longer wavelength, transitions. We had previously included lines from the Opacity Project data base, which tends to include higher energy, shorter wavelength, transitions. These were combined with various forms of the ‘g-bar’ approximation, a highly approximate method of estimating collision rates. For several iron ions the two data bases are almost entirely complementary. We adopt a hybrid approach in which we use Chianti where possible, supplemented by lines from the Opacity Project for shorter wavelength transitions. The total cooling including the lightest 30 elements differs from some previous calculations by significant amounts
Radiative Cooling II: Effects of Density and Metallicity
This work follows Lykins et al. discussion of classic plasma cooling function
at low density and solar metallicity. Here we focus on how the cooling function
changes over a wide range of density (n_H<10^12 cm^(-3)) and metallicity (Z<30Z
_sun ). We find that high densities enhance the ionization of elements such as
hydrogen and helium until they reach local thermodynamic equilibrium. By charge
transfer, the metallicity changes the ionization of hydrogen when it is
partially ionized. We describe the total cooling function as a sum of four
parts: those due to H&He, the heavy elements, electron-electron bremsstrahlung
and grains. For the first 3 parts, we provide a low-density limit cooling
function, a density dependence function, and a metallicity dependence function.
These functions are given with numerical tables and analytical fit functions.
For grain cooling, we only discuss in ISM case. We then obtain a total cooling
function that depends on density, metallicity and temperature. As expected,
collisional de-excitation suppresses the heavy elements cooling. Finally, we
provide a function giving the electron fraction, which can be used to convert
the cooling function into a cooling rate.Comment: Published by MNRAS, online tables can be found at
http://mnras.oxfordjournals.org/content/suppl/2014/04/28/stu514.DC
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