Toward an Understanding of the Systematic Uncertainties in Deriving the Primordial Helium Abundance from H II Region Observations

A new determination of the pregalactic helium abundance based on the Magellanic Clouds H II regions is discussed. This determination amounts to Yp = 0.2345 ± 0.0030 and is compared with those derived from giant extragalactic H II regions in systems with extremely low heavy elements content. It is suggested that the higher primordial value derived by other authors from giant H II region complexes could be due to two systematic effects: the presence of neutral hydrogen inside the helium Strömgren sphere and the presence of temperature variations inside the observed volume.

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The primordial helium abundance determination using multicomponent photoionization modelling of low-metallicity H II regions

Advances in Astronomy and Space Physics ◽

10.17721/2227-1481.8.16-23 ◽

2018 ◽

Vol 8 (1) ◽

pp. 16-23

Author(s):

I. Koshmak ◽

B. Melekh

Keyword(s):

Chemical Compositions ◽

H Ii Regions ◽

Helium Abundance ◽

Rotating Stars ◽

Chemical Abundances ◽

Free Expansion ◽

Outer Component ◽

Low Metallicity ◽

H Ii Region ◽

Primordial Helium

The method for the multicomponent photoionization modelling (MPhM) of low-metallicity H II regions surrounding the starburst region was developed. The internal structure of the H II region has been determined using the evolutionary modelling of the superwind bubble surrounding the star-forming region. Models of Chevalier and Clegg (1985) and Weaver et al. (1977) have been used to determine the radial distribution of the gas density, the velocity of gas layers, and the temperature within internal components (the region of the superwind free expansion and the cavity, respectively). The chemical abundances in region of the superwind free expansion were obtained from the evolutionary population synthesis with including of rotating stars. The chemical abundances within cavity were defined by averaging over mass the chemical compositions of mixture of the abundances of gas from superwind and ones within outer component, because of gas evaporation from external component into the cavity. External components of our models describe a high-density, thin shell of gas formed by superwind shock and a typical undisturbed hydrodynamically H II region, respectively. Evolutionary grids of multicomponent low-metallicity models are calculated. A comparative analysis of the results of their calculation with the observed data has been carried out. The ionic abundances averaged over modelling volume as well as chemical composition assumed in models were used to derive the new expressions for ionization-correction factors that were used to redetermine the chemical compositions of 88 H II regions in blue compact dwarf galaxies. It must be noticed that we used for this propose the ionic abundances obtained by Izotov et al. (2007). In result the primordial helium abundance and its enrichment during stellar chemical evolution of matter were determined.

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A new determination of the primordial helium abundance using the analyses of H ii region spectra from SDSS

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/stab215 ◽

2021 ◽

Vol 502 (2) ◽

pp. 3045-3056

Author(s):

O A Kurichin ◽

P A Kislitsyn ◽

V V Klimenko ◽

S A Balashev ◽

A V Ivanchik

Keyword(s):

Sloan Digital Sky Survey ◽

H Ii Regions ◽

Helium Abundance ◽

Physical Conditions ◽

Sky Survey ◽

H Ii Region ◽

Standard Cosmological Model ◽

Primordial Helium ◽

Good Agreement

ABSTRACT The precision measurement of the primordial helium abundance Yp is a powerful probe of the early Universe. The most common way to determine Yp is the analyses of observations of metal-poor H ii regions found in blue compact dwarf galaxies. We present the spectroscopic sample of 100 H ii regions collected from the Sloan Digital Sky Survey. The final analysed sample consists of our sample and HeBCD data base from Izotov et al. (2007). We use a self-consistent procedure to determine physical conditions, current helium abundances, and metallicities of the H ii regions. From a regression to zero metallicity, we have obtained Yp = 0.2462 ± 0.0022, which is one of the most stringent constraints obtained with such methods up to date and is in a good agreement with the Planck result $Y_{\rm p}^{\it {\mathrm{ Planck}}} = 0.2471 \pm 0.0003$. Using the determined value of Yp and the primordial deuterium abundance taken from Particle Data Group (Zyla et al. 2020) we put a constraint on the effective number of neutrino species Neff = 2.95 ± 0.16, which is consistent with the Planck one Neff = 2.99 ± 0.17. Further increase of statistics potentially allows us to achieve Planck accuracy, which in turn will become a powerful tool for studying the self-consistency of the standard cosmological model and/or physics beyond.

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Determining the primordial helium abundance and UV background using fluorescent emission in star-free dark matter haloes

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/stz3573 ◽

2019 ◽

Vol 492 (2) ◽

pp. 2151-2160 ◽

Cited By ~ 1

Author(s):

Calvin Sykes ◽

Michele Fumagalli ◽

Ryan Cooke ◽

Tom Theuns

Keyword(s):

Dark Matter ◽

Particle Physics ◽

Standard Model Prediction ◽

Line Emission ◽

Helium Abundance ◽

Fundamental Particle ◽

Observational Measures ◽

Systematic Uncertainties ◽

Primordial Helium ◽

Hydrodynamical Simulations

ABSTRACT Observational measures of the primordial helium mass fraction, YP, are of interest for cosmology and fundamental particle physics. Current measures obtained from ${\text{H}\, \small {II}}$ regions agree with the Standard Model prediction to approximately 1 per cent precision, although these determinations may be affected by systematic uncertainties. This possibility can only be tested by independently measuring the helium abundance in new ways. Here, we propose a novel method to obtain a measurement of YP using hydrogen and helium recombination line emission from REionization-Limited HI Clouds (RELHICs): pristine, gas-rich but star-free low-mass dark matter haloes whose existence is predicted by hydrodynamical simulations. Although expected to be uncommon and intrinsically faint in emission, the primordial composition and simple physical properties of these objects make them an ideal laboratory to determine YP. We present radiative transfer simulations to demonstrate the effectiveness of this approach, finding that a comparison of the emission in H and He lines, either via their volumetric emissivities, or integrated properties such as the surface brightness and total flux, may be used to infer YP. Furthermore, we show that RELHICs can be used to provide an entirely novel constraint on the spectral slope of the ultraviolet background, and discuss the possibility of measuring this slope and the primordial helium abundance simultaneously.

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