Synthesis of Chemical Elements and Solid Structures in Atomic- Nuclear Reactions in Dense Gas-Metal Systems Irradiated by γ Rays

SummaryIsotopic shifts in the lines of the heavy elements in Ap stars, and the characteristic abundance pattern of these elements point to the fact that we are observing mainly the products of rapid neutron capture. The peculiar A stars may be treated as the show windows for the products of a recent r-process in their neighbourhood. This process can be located either in Supernovae exploding in a binary system in which the present Ap stars were secondaries, or in Supernovae exploding in young clusters. Secondary processes, e.g. spontaneous fission or nuclear reactions with highly abundant fission products, may occur further with the r-processed material in the surface of the Ap stars. The role of these stars to the theory of nucleosynthesis and to nuclear physics is emphasized.

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ABSOLUTE STANDARDIZATION OF RADIOACTIVE NEUTRON SOURCES: II. THE USE OF THE F19(α, n)Na22 REACTION

Canadian Journal of Physics ◽

10.1139/p59-062 ◽

1959 ◽

Vol 37 (5) ◽

pp. 550-556 ◽

Cited By ~ 7

Author(s):

K. W. Geiger

Keyword(s):

Nuclear Reactions ◽

Emission Rate ◽

Neutron Emission ◽

National Research Council ◽

Neutron Output ◽

Neutron Sources ◽

Neutron Thermalization ◽

Γ Rays ◽

Absolute Standardization ◽

Good Agreement

Fluorine has only one stable isotope, F19. If neutrons are produced by the F19(α, n)Na22 reaction the neutron output can be calculated from the yield of the resulting radioactive Na22. The growth of Na22 (half-life, 2.58 years) has been measured in a neutron source consisting originally of 1.6 curies Po210 mixed with CaF2 powder. Since Na22 is a positron emitter, discrimination against γ-rays from Po210 and from nuclear reactions could be achieved by detecting the two positron annihilation quanta in coincidence. The Na22 growth has been followed over 20 months and is in agreement with the theoretical growth curve. Comparison with a calibrated Na22 source yielded a neutron emission rate of (10.70 ± 0.25) × 104 sec−1. This resulted in a neutron emission rate of (3.16 ± 0.10) × 106 sec−1 for the Ra-α-Be source of the National Research Council, in good agreement with (3.22 ± 0.05) × 106 sec−1 obtained by a neutron thermalization method.

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Physical mechanisms of mixing in stellar interiors

Symposium - International Astronomical Union ◽

10.1017/s0074180900031363 ◽

1984 ◽

Vol 105 ◽

pp. 491-512

Author(s):

Evry Schatzman

Keyword(s):

Diffusion Equation ◽

Stellar Evolution ◽

Turbulent Mixing ◽

Nuclear Reactions ◽

Chemical Elements ◽

Solar Neutrinos ◽

Stellar Structure ◽

Physical Mechanisms ◽

Nitrogen Abundance ◽

Stellar Interiors

The different mechanisms by which mixing can take place in stellar interiors are considered : the classical Rayleigh-Benard instability with penetrative convection and over-shooting, semi-convection, gravitationnal and radiative settling, turbulent mixing. The latter mechanism is thoroughly described, from the driving force of turbulent mixing to its influence on stellar structure, stellar evolution and the analysis of the corresponding observationnal data.Turbulent mixing has to be considered each time the building up of a concentration gradient takes place, either by gravitationnal or radiative settling or by nuclear reactions. Turbulent mixing, as a first approximation, can be described by an isotropic diffusion coefficient. The process is then governed by a diffusion equation. The behaviour of the solution of the diffusion equation needs some explanation in order to be well understood.A number of examples concerning surface abundances of chemical elements are given (3He, 7Li, Be, 12C, 13C, 14N), as well as a discussion of the solar neutrinos problem.The building up of a µ-barrier, which stops the turbulence allows stellar evolution towards the giant branch and explains nitrogen abundance at the surface of giants of the first ascending branch.Turbulent mixing is also of some importance for the transfer of angular momentum and has to be taken into account for explaining the abundance of the elements in Wolf-Rayet stars.

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THE EMISSION OF γ-RAYS IN NUCLEAR REACTIONS

Journal of the American Chemical Society ◽

10.1021/ja01327a509 ◽

1934 ◽

Vol 56 (12) ◽

pp. 2786-2787

Author(s):

William D. Harkins ◽

David M. Gans

Keyword(s):

Nuclear Reactions ◽

Γ Rays

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Stellar Convective Cores

Symposium - International Astronomical Union ◽

10.1017/s0074180900238321 ◽

1998 ◽

Vol 185 ◽

pp. 73-80

Author(s):

I.W. Roxburgh

Keyword(s):

Internal Structure ◽

Binary Stars ◽

Nuclear Reactions ◽

Chemical Elements ◽

Theoretical Models ◽

Large Mass ◽

Subsequent Evolution ◽

Mixing Processes ◽

Processed Material ◽

Nuclear Burning

The internal structure of stars is governed by hydrostatic support, the distribution of the chemical elements, the transport of energy by radiation and convection, and the liberation of energy by nuclear reactions. The evolution of stars is primarily determined by the changing composition due to the nuclear burning of elements in the central parts of the star, and the redistribution of the products of these reactions by mixing processes. The dominant mixing process is convection: it governs the extent of the mixed cores in moderate and large mass main sequence stars and their subsequent evolution, it mixes nuclear processed material into the envelopes of giants affecting the composition of material ejected into the interstellar medium, thereby affecting the chemical (and luminosity) evolution of galaxies. Understanding convection is essential if one is to understand the evolution of stars. Here I am concerned with convection in stellar cores and in particular with the extension of these cores by the penetration of convective motions into the surrounding stable layers affecting the internal structure and enlarging the chemically mixed region, which in turn affects the subsequent evolution. I briefly discuss a number of approaches to this problem: isochrone fitting of clusters and binary stars; simple theoretical models, the integral constraint, numerical simulation and what we can hope to get from asteroseismological observations of individual stars and of clusters and stellar groups.

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Origin and status of LUNA at Gran Sasso

Modern Physics Letters A ◽

10.1142/s0217732314300389 ◽

2014 ◽

Vol 29 (34) ◽

pp. 1430038

Author(s):

Carlo Broggini ◽

Keyword(s):

Nuclear Physics ◽

Nuclear Reactions ◽

Chemical Elements ◽

Nuclear Astrophysics ◽

Hydrogen Burning ◽

Proton Proton ◽

Oxygen Cycle ◽

Comprehensive Picture ◽

Deep Underground ◽

The Universe

The ultimate goal of nuclear astrophysics, the union of nuclear physics and astronomy, is to provide a comprehensive picture of the nuclear reactions which power the stars and, in doing so, synthesize the chemical elements. Deep underground in the Gran Sasso Laboratory the key reactions of the proton–proton chain and of the carbon–nitrogen–oxygen cycle have been studied down to the energies of astrophysical interest. The main results obtained in the past 20 years are reviewed and their influence on our understanding of the properties of the neutrino, the Sun, and the Universe itself is discussed. Finally, future developments of underground nuclear astrophysics beyond the study of hydrogen burning are outlined.

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Superheavy elements

Pure and Applied Chemistry ◽

10.1351/pac200476091715 ◽

2004 ◽

Vol 76 (9) ◽

pp. 1715-1734 ◽

Cited By ~ 6

Author(s):

Yu. Ts. Oganessian

Keyword(s):

Nuclear Reactions ◽

Chemical Elements ◽

Magic Nucleus ◽

Superheavy Elements ◽

Nuclear Chemistry ◽

Fusion Reactions ◽

Spherical Shells ◽

Flerov Laboratory ◽

Theoretical Predictions ◽

Chemistry Division

One of the fundamental outcomes of nuclear theory is the predicted existence of increased stability in the region of unknown superheavy elements. This hypothesis, proposed more than 35 years ago and intensively developed during all this time, significantly extends the limits of existence of chemical elements. “Magic ”nuclei with closed proton and neutron shells possess maximum binding energy. For the heaviest nuclides, a considerable stability is predicted close to the deformed shells with Z = 108, N = 162. Even higher stability is expected for the neutron-rich nuclei close to the spherical shells with Z = 114 (possibly also at Z = 120, 122) and N = 184, coming next to the well-known “doubly magic ”nucleus 208 Pb. The present paper describes the experiments aimed at the synthesis of nuclides with Z = 113–116, 118 and N = 170–177, produced in the fusion reactions of the heavy isotopes of Pu, Am, Cm, and Cf with 48Ca projectiles.The energies and half-lives of the new nuclides, as well as those of their daughter nuclei (Z < 113) qualitatively agree with the theoretical predictions. The question, which is the nucleus, among the superheavy ones, that has the longest half-life is also considered. It has been shown that, if the lifetime of the most stable isotopes, in particular, the isotopes of element 108 (Hs), is ≥ 5 ×107 years, they can be found in natu ral objects. The experiments were carried out during 2001–2003 in the Flerov Laboratory of Nuclear Reactions (JINR, Dubna) in collaboration with the Analytical and Nuclear Chemistry Division (LLNL, Livermore).

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Intense proton beam current measurement via prompt γ rays from nuclear reactions

Review of Scientific Instruments ◽

10.1063/1.1135275 ◽

1978 ◽

Vol 49 (10) ◽

pp. 1384-1387 ◽

Cited By ~ 14

Author(s):

J. Golden ◽

R. A. Mahaffey ◽

J. A. Pasour ◽

F. C. Young ◽

C. A. Kapetanakos

Keyword(s):

Proton Beam ◽

Nuclear Reactions ◽

Beam Current ◽

Current Measurement ◽

Γ Rays ◽

Beam Current Measurement

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Magnetic Fields And High-Temperature Superconductivity In Excited Liquids. Unknown Particles

Radioelectronics Nanosystems Information Technologies ◽

10.17725/rensit.2021.13.303 ◽

2021 ◽

Vol 13 (3) ◽

pp. 303-318

Author(s):

Gennady V. Mishinsky ◽

Keyword(s):

Magnetic Fields ◽

Electric Current ◽

Nuclear Reactions ◽

High Temperature Superconductivity ◽

Chemical Elements ◽

Liquid Media ◽

Strong Magnetic Fields ◽

Atomic Nuclei ◽

Self Consistent Field ◽

Unidirectional Motion

The article presents a number of experiments in liquid media on the transformation (transmutation) of atomic nuclei of some chemical elements into atomic nuclei of other chemical elements. In the theory of low-energy nuclear reactions, the transmutation of atomic nuclei occurs in strong magnetic fields, more than 30 T. Magnetic fields appear in ionized liquid media as a result of the unidirectional motion of an ensemble of electrons. The exchange interaction between electrons with parallel spins forms a self-consistent field in the medium, in which electrons pair into orthobosons with S = 1ћ. Orthobosons are attracted to each other and form orthoboson “solenoids” - “capsules” with strong magnetic fields inside. “Capsules” can fly out of liquid media, and then they are registered as unknown particles with strange properties. In some cases, when an electric current passes through the liquid, the electric current can be realized in the form of orthobosonic “solenoids” connected in continuous “filaments” from one electrode to another. Such “filaments” exhibit characteristics of superconductivity.

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The radioactive nuclei and in the Cosmos and in the solar system

Publications of the Astronomical Society of Australia ◽

10.1017/pasa.2021.48 ◽

2021 ◽

Vol 38 ◽

Author(s):

R. Diehl ◽

M. Lugaro ◽

A. Heger ◽

A. Sieverding ◽

X. Tang ◽

...

Keyword(s):

Solar System ◽

Nuclear Reactions ◽

Chemical Elements ◽

Nuclear Fusion ◽

Cosmic Ray ◽

Big Bang ◽

Lessons Learned ◽

Radioactive Isotopes ◽

Fusion Reactions ◽

Nuclear Fusion Reactions

Abstract The cosmic evolution of the chemical elements from the Big Bang to the present time is driven by nuclear fusion reactions inside stars and stellar explosions. A cycle of matter recurrently re-processes metal-enriched stellar ejecta into the next generation of stars. The study of cosmic nucleosynthesis and this matter cycle requires the understanding of the physics of nuclear reactions, of the conditions at which the nuclear reactions are activated inside the stars and stellar explosions, of the stellar ejection mechanisms through winds and explosions, and of the transport of the ejecta towards the next cycle, from hot plasma to cold, star-forming gas. Due to the long timescales of stellar evolution, and because of the infrequent occurrence of stellar explosions, observational studies are challenging, as they have biases in time and space as well as different sensitivities related to the various astronomical methods. Here, we describe in detail the astrophysical and nuclear-physical processes involved in creating two radioactive isotopes useful in such studies, $^{26}\mathrm{Al}$ and $^{60}\mathrm{Fe}$ . Due to their radioactive lifetime of the order of a million years, these isotopes are suitable to characterise simultaneously the processes of nuclear fusion reactions and of interstellar transport. We describe and discuss the nuclear reactions involved in the production and destruction of $^{26}\mathrm{Al}$ and $^{60}\mathrm{Fe}$ , the key characteristics of the stellar sites of their nucleosynthesis and their interstellar journey after ejection from the nucleosynthesis sites. This allows us to connect the theoretical astrophysical aspects to the variety of astronomical messengers presented here, from stardust and cosmic-ray composition measurements, through observation of $\gamma$ rays produced by radioactivity, to material deposited in deep-sea ocean crusts and to the inferred composition of the first solids that have formed in the Solar System. We show that considering measurements of the isotopic ratio of $^{26}\mathrm{Al}$ to $^{60}\mathrm{Fe}$ eliminate some of the unknowns when interpreting astronomical results, and discuss the lessons learned from these two isotopes on cosmic chemical evolution. This review paper has emerged from an ISSI-BJ Team project in 2017–2019, bringing together nuclear physicists, astronomers, and astrophysicists in this inter-disciplinary discussion.

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