CNO andLi6from big-bang nucleosynthesis—Impact of unmeasured reaction rates

We review the recent progress in the Big-Bang nucleosynthesis which includes the standard and nonstandard theory of cosmology, effects of neutrino degeneracy, and inhomogeneous nucleosynthesis within the framework of a Friedmann model. As for a nonstandard theory of gravitation, we adopt a Brans–Dicke theory which incorporates a cosmological constant. We constrain various parameters associated with each subject.

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3He(α,γ)7Be and 3H(α,γ)7Li reaction rates and implication for Big Bang nucleosynthesis in the potential model

International Journal of Modern Physics Conference Series ◽

10.1142/s2010194519600140 ◽

2019 ◽

Vol 49 ◽

pp. 1960014 ◽

Cited By ~ 1

Author(s):

S. A. Turakulov ◽

E. M. Tursunov

Keyword(s):

Potential Model ◽

Reaction Rates ◽

Big Bang ◽

Abundance Ratio ◽

Recent Measurement ◽

Big Bang Nucleosynthesis ◽

Body Potential ◽

Text Element ◽

Good Agreement

The reaction rates of the direct astrophysical capture processes [Formula: see text] and [Formula: see text], as well as the abundance of the [Formula: see text] element are estimated in the framework of a two-body potential model. The estimated [Formula: see text] abundance ratio of [Formula: see text] is in a very good agreement with the recent measurement [Formula: see text] of the LUNA collaboration.

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QED corrections to Big-Bang nucleosynthesis reaction rates

Physical Review C ◽

10.1103/physrevc.102.015803 ◽

2020 ◽

Vol 102 (1) ◽

Cited By ~ 1

Author(s):

Cyril Pitrou ◽

Maxim Pospelov

Keyword(s):

Reaction Rates ◽

Big Bang ◽

Big Bang Nucleosynthesis

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Underground Nuclear Astrophysics: Present and future of the LUNA experiment

EPJ Web of Conferences ◽

10.1051/epjconf/201920901043 ◽

2019 ◽

Vol 209 ◽

pp. 01043

Author(s):

Carlo Gustavino

Keyword(s):

Nuclear Astrophysics ◽

Reaction Rates ◽

Big Bang ◽

Scientific Program ◽

Thermonuclear Reaction ◽

Big Bang Nucleosynthesis ◽

Celestial Bodies ◽

Deep Underground ◽

The Big Bang ◽

Nuclear Processes

The evolution of celestial bodies is regulated by gravitation and thermonuclear reaction rates, while the Big Bang nucleosynthesis is the result of nuclear processes in a rapidly expanding Universe. The LUNA Collaboration has shown that, by exploiting the ultra low background achievable deep underground, it is possible to study the relevant nuclear processes down to the nucleosynthesis energy inside stars and during the first minutes of Universe. In this paper the main results of LUNA are overviewed, as well as the scientific program the forthcoming 3.5 MV underground accelerator.

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New reaction rates for the destruction of 7Be during big bang nucleosynthesis measured at CERN/n_TOF and their implications on the cosmological lithium problem

EPJ Web of Conferences ◽

10.1051/epjconf/202023907001 ◽

2020 ◽

Vol 239 ◽

pp. 07001

Author(s):

A. Mengoni ◽

L.A. Damone ◽

M. Barbagallo ◽

O. Aberle ◽

V. Alcayne ◽

...

Keyword(s):

Energy Range ◽

Thermal Energy ◽

Cross Sections ◽

Reaction Rates ◽

Big Bang ◽

Reaction Cross ◽

Big Bang Nucleosynthesis ◽

Destruction Rate ◽

Viable Solution ◽

Reaction Cross Sections

New measurements of the 7Be(n,α)4He and 7Be(n,p)7Li reaction cross sections from thermal to keV neutron energies have been recently performed at CERN/n_TOF. Based on the new experimental results, astrophysical reaction rates have been derived for both reactions, including a proper evaluation of their uncertainties in the thermal energy range of interest for big bang nucleosynthesis studies. The new estimate of the 7Be destruction rate, based on these new results, yields a decrease of the predicted cosmological 7Li abundance insufficient to provide a viable solution to the cosmological lithium problem.

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Bayesian Estimation of the D(p,γ)3He Thermonuclear Reaction Rate

The Astrophysical Journal ◽

10.3847/1538-4357/ac1db0 ◽

2021 ◽

Vol 923 (1) ◽

pp. 49

Author(s):

Joseph Moscoso ◽

Rafael S. de Souza ◽

Alain Coc ◽

Christian Iliadis

Keyword(s):

Reaction Rates ◽

Big Bang ◽

Baryon Density ◽

Thermonuclear Reaction ◽

Big Bang Nucleosynthesis ◽

Highly Sensitive ◽

Theoretical Predictions ◽

Reliable Knowledge ◽

Percent Accuracy ◽

The Big Bang

Abstract Big bang nucleosynthesis (BBN) is the standard model theory for the production of light nuclides during the early stages of the universe, taking place about 20 minutes after the big bang. Deuterium production, in particular, is highly sensitive to the primordial baryon density and the number of neutrino species, and its abundance serves as a sensitive test for the conditions in the early universe. The comparison of observed deuterium abundances with predicted ones requires reliable knowledge of the relevant thermonuclear reaction rates and their corresponding uncertainties. Recent observations reported the primordial deuterium abundance with percent accuracy, but some theoretical predictions based on BBN are in tension with the measured values because of uncertainties in the cross section of the deuterium-burning reactions. In this work, we analyze the S-factor of the D(p,γ)3He reaction using a hierarchical Bayesian model. We take into account the results of 11 experiments, spanning the period of 1955–2021, more than any other study. We also present results for two different fitting functions, a two-parameter function based on microscopic nuclear theory and a four-parameter polynomial. Our recommended reaction rates have a 2.2% uncertainty at 0.8 GK, which is the temperature most important for deuterium BBN. Differences between our rates and previous results are discussed.

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Revised uncertainties in Big Bang Nucleosynthesis

International Journal of Modern Physics E ◽

10.1142/s0218301317410087 ◽

2017 ◽

Vol 26 (08) ◽

pp. 1741008 ◽

Cited By ~ 8

Author(s):

M. Foley ◽

N. Sasankan ◽

M. Kusakabe ◽

G. J. Mathews

Keyword(s):

Monte Carlo ◽

Monte Carlo Analysis ◽

Reaction Rates ◽

Big Bang ◽

Effective Number ◽

Big Bang Nucleosynthesis ◽

The Big Bang

Big Bang Nucleosynthesis (BBN) explores the first few minutes of nuclei formation during the Big Bang. We present updated 2[Formula: see text] for the abundances of the four primary light nuclides — D, 3He, 4He, and 7Li — in BBN. A modified standard BBN code was used in a Monte Carlo analysis of the nucleosynthesis uncertainties as a function of the baryon-to-photon ratio. Reaction rates were updated to those of NACRE, REACLIB, and [Formula: see text]-Matrix calculations. The results were then used to derive a new constraint on the effective number of neutrinos.

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Limits on brane-world and particle dark radiation from big bang nucleosynthesis and the CMB

International Journal of Modern Physics E ◽

10.1142/s0218301317410075 ◽

2017 ◽

Vol 26 (08) ◽

pp. 1741007 ◽

Cited By ~ 9

Author(s):

N. Sasankan ◽

Mayukh R. Gangopadhyay ◽

G. J. Mathews ◽

M. Kusakabe

Keyword(s):

Energy Density ◽

Power Spectrum ◽

Light Element ◽

Reaction Rates ◽

Big Bang ◽

Brane World ◽

Expansion Rate ◽

Big Bang Nucleosynthesis ◽

Dark Radiation ◽

Element Abundances

The term dark radiation is used both to describe a noninteracting neutrino species and as a correction to the Friedmann Equation in the simplest five-dimensional (5D) RS-II brane-world cosmology. In this paper, we consider the constraints on both the meanings of dark radiation-based upon the newest results for light-element nuclear reaction rates, observed light-element abundances and the power spectrum of the Cosmic Microwave Background (CMB). Adding dark radiation during big bang nucleosynthesis (BBN) alters the Friedmann expansion rate causing the nuclear reactions to freeze out at a different temperature. This changes the final light element abundances at the end of BBN. Its influence on the CMB is to change the effective expansion rate at the surface of the last scattering. We find that the BBN constraint reduces the allowed range for both types of dark radiation at 10[Formula: see text]Mev to between [Formula: see text] and [Formula: see text] of the total background energy density at 10[Formula: see text]Mev. Combining this result with fits to the CMB power spectrum, produces different results for particle versus brane-world dark radiation. In the brane-world, the range decreases from [Formula: see text] to [Formula: see text]. Thus, we find that the ratio of dark radiation to the background total relativistic mass energy density [Formula: see text] is consistent with zero although there remains a very slight preference for a positive (rather than negative) contribution.

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Effects of transient nonthermal particles on the big bang nucleosynthesis

International Journal of Modern Physics E ◽

10.1142/s0218301320500123 ◽

2020 ◽

Vol 29 (03) ◽

pp. 2050012

Author(s):

Tae-Sun Park ◽

Kyung Joo Min ◽

Seung-Woo Hong

Keyword(s):

Reaction Rates ◽

Big Bang ◽

Temporal Region ◽

Temporal Position ◽

Strongly Correlated ◽

Light Elements ◽

Big Bang Nucleosynthesis ◽

Wide Range ◽

The Big Bang ◽

Nonthermal Particles

The effects of introducing a small amount of nonthermal distribution (NTD) of elements in big bang nucleosynthesis (BBN) are studied by allowing a fraction of the NTD to be time-dependent so that it contributes only during a certain period of the BBN evolution. The fraction is modeled as a Gaussian-shaped function of [Formula: see text], where [Formula: see text] is the temperature of the cosmos, and thus the function is specified by three parameters; the central temporal position, the width and the magnitude. The change in the average nuclear reaction rates due to the presence of the NTD is assumed to be proportional to the Maxwellian reaction rates but with temperature [Formula: see text], [Formula: see text] being another parameter of our model. By scanning a wide four-dimensional parametric space at about half a million points, we have found about 130 points with [Formula: see text], at which the predicted primordial abundances of light elements are consistent with the observations. The magnitude parameter [Formula: see text] of these points turns out to be scattered over a very wide range from [Formula: see text] to [Formula: see text], and the [Formula: see text]-parameter is found to be strongly correlated with the magnitude parameter [Formula: see text]. The temperature region with [Formula: see text] or the temporal region [Formula: see text][Formula: see text]s seems to play a central role in lowering [Formula: see text].

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