Your search keyword '"Ya Rusanov"' showing total 6 results

1. Microstructure and properties of single-crystal rare-earth oxide fibers

Author

Vladimir B. Tsvetkov, S. Ya. Rusanov, V. V. Kashin, Valerii V Voronov, and L. D. Iskhakova

Subjects

Materials science, Scanning electron microscope, Oxide, Mineralogy, Microstructure, Microanalysis, Surfaces, Coatings and Films, chemistry.chemical_compound, Brittleness, chemistry, Thin film, Composite material, Single crystal, Electron backscatter diffraction

Abstract

Single-crystal Ln2O3 (Ln = Sm, Eu, Gd) fibers are grown by the laser-heated miniature pedestal technique. The relationship between the microstructure of fibers and their plasticity is analyzed using scanning electron microscopy, energy-dispersive microanalysis, electron backscatter diffraction, and X-ray methods. It is shown that the distinction between ductile and brittle fibers is determined basically by the difference in their microstructure. The fracture of samarium oxide fibers is associated with the formation of oxycarbonate phases on their surface. The most promising are the fibers of gadolinium oxide, having the most perfect microstructure, moisture and a carbon dioxide resistance, and a wide range of transparency.

Published

2011

2. Investigation of the 208Pb(18O, f) fission reaction: Mass-energy distributions of fission fragments and their correlation with the gamma-ray multiplicity

Author

I. V. Pokrovsky, V.V. Pashkevich, M. G. Itkis, G. G. Chubarian, A. Ya. Rusanov, V. S. Salamatin, and N. A. Kondratiev

Subjects

Nuclear reaction, Physics, Nuclear and High Energy Physics, Cold fission, Cluster decay, Fission, Nuclear Theory, Gamma ray, Kinetic energy, Atomic and Molecular Physics, and Optics, Nuclear physics, Nuclear fission, Multiplicity (chemistry), Atomic physics, Nuclear Experiment

Abstract

The mass-energy distributions of fragments originating from the fission of the compound nucleus 226Th and their correlations with the multiplicity of gamma rays emitted from these fragments are measured and analyzed in 18O + 208Pb interaction induced by projectile oxygen ions of energy in the range E lab = 78–198.5 MeV. Manifestations of an asymmetric fission mode, which is damped exponentially with increasing E lab, are demonstrated. Theoretical calculations of fission valleys reveal that only two independent valleys, symmetric and asymmetric, exist in the vicinity of the scission point. The dependence of the multiplicity of gamma rays emitted from both fission fragments on their mass, Mγ(M), has a complicated structure and is highly sensitive to shell effects in both primary and final fragments. A two-component analysis of the dependence Mγ(M) shows that the asymmetric mode survives in fission only at low partial-wave orbital angular momenta of compound nuclei. It is found that, for all E lab, the gamma-ray multiplicity Mγ as a function of the total kinetic energy (TKE) of fragments, Mγ(TKE), decreases linearly with increasing TKE. An analysis of the energy balance in the fission process at the laboratory energy of E lab = 78 MeV revealed the region of cold fission of fragments whose total kinetic energy is TKE ∼Q max.

Published

2008

3. Investigation of the reaction 208Pb(18O, f): Fragment spins and phenomenological analysis of the angular anisotropy of fission fragments

Author

V. V. Pashkevich, V. S. Salamatin, I. V. Pokrovsky, A. Ya. Rusanov, P. N. Nadtochy, M. G. Itkis, G. D. Adeev, G. G. Chubarian, and A. V. Karpov

Subjects

Physics, Nuclear and High Energy Physics, Angular momentum, Fission, Nuclear Theory, Coulomb barrier, Moment of inertia, Atomic and Molecular Physics, and Optics, Total angular momentum quantum number, Saddle point, Atomic physics, Multiplicity (chemistry), Nuclear Experiment, Anisotropy

Abstract

The average multiplicity of gamma rays emitted by fragments originating from the fission of 226Th nuclei formed via a complete fusion of 18O and 208Pb nuclei at laboratory energies of 18O projectile ions in the range E lab = 78–198.5 MeV is measured and analyzed. The total spins of fission fragments are found and used in an empirical analysis of the energy dependence of the anisotropy of these fragments under the assumption that their angular distributions are formed in the vicinity of the scission point. The average temperature of compound nuclei at the scission point and their average angular momenta in the entrance channel are found for this analysis. Also, the moments of inertia are calculated for this purpose for the chain of fissile thorium nuclei at the scission point. All of these parameters are determined at the scission point by means of three-dimensional dynamical calculations based on Langevin equations. A strong alignment of fragment spins is assumed in analyzing the anisotropy in question. In that case, the energy dependence of the anisotropy of fission fragments is faithfully reproduced at energies in excess of the Coulomb barrier (E c.m. − E B ≥ 30 MeV). It is assumed that, as the excitation energy and the angular momentum of a fissile nucleus are increased, the region where the angular distributions of fragments are formed is gradually shifted from the region of nuclear deformations in the vicinity of the saddle point to the region of nuclear deformations in the vicinity of the scission point, the total angular momentum of the nucleus undergoing fission being split into the orbital component, which is responsible for the anisotropy of fragments, and the spin component. This conclusion can be qualitatively explained on the basis of linear-response theory.

Published

2007

4. Investigation of the reaction 208Pb(18O, f): Folding angular distributions of fission fragments and gamma-ray multiplicity

Author

V. S. Salamatin, G. G. Chubarian, N. A. Kondratiev, A. Ya. Rusanov, M. G. Itkis, and I. V. Pokrovsky

Subjects

Physics, Nuclear and High Energy Physics, Cold fission, Angular momentum, Cluster decay, Fission, Nuclear Theory, Gamma ray, Atomic and Molecular Physics, and Optics, Ion, Nuclear physics, Atomic physics, Multiplicity (chemistry), Nuclear Experiment, Nucleon

Abstract

Correlations between folding angular distributions of fission fragments and the gamma-ray multiplicity are studied for 18O + 208Pb interactions at energies of the beam of 18O ions in the range E lab = 78–198.5 MeV. The probabilities are determined for complete-and incomplete-fusion processes inevitably followed by the fission of nuclei formed in these processes. It is found that the probability of incomplete fusion followed by fission increases with increasing energy of bombarding ions. It is shown that, for the incomplete-fusion process, folding angular distributions of fission fragments have a two-component structure. The width of folding angular distributions (FWHM) for complete fusion grows linearly with increasing energy of 18O ions. The multiplicity of gamma rays from fission fragments as a function of the linear-momentum transfer behaves differently for different energies of projectile ions. This circumstance is explained here by the distinction between the average angular momenta of participant nuclei in the fusion and fission channels, which is due to the difference in the probabilities of fission in the cases where different numbers of nucleons are captured by the target nucleus.

Published

2007

5. The effect of the entrance channel on the fission of 216Ra

Author

A. M. Stefanini, S. Beghini, I. M. Itkis, E. M. Kozulin, A. M. Vinodkumar, O. Dorvaux, G. N. Kniajeva, G. Montagnoli, M. Trotta, N. A. Kondratiev, R. N. Sagaidak, Louise Stuttge, Neil Rowley, Ya Rusanov, L. Corradi, M. G. Itkis, Yu Chizhov, Francis Hanappe, V. M. Voskressensky, I. V. Pokrovsky, and Fernando Scarlassara

Subjects

Physics, Nuclear and High Energy Physics, Cluster decay, Fission, Nuclear Theory, Atomic and Molecular Physics, and Optics, Entrance channel, medicine.anatomical_structure, Yield (chemistry), medicine, Atomic physics, Nuclear Experiment, Nucleus, Excitation, Radioactive decay

Abstract

We have studied mass-energy distributions (MED) of fission fragments using two projectile-target combinations, 12C + 204Pb and 48Ca + 168Er, leading to the same compound nucleus 216Ra at the excitation energy E*∼40 MeV. It has been found that the contribution of the asymmetric mode in the case of the former reaction is 1.5%, and it is 30% in the case of the latter one. We connect such a sharp increase in the yield of asymmetric products in the 48Ca + 168Er reaction with the quasifission process, the MED of which have a clearly expressed shell structure. The characteristics of the fission fragment MED are of such a kind that they can be interpreted by analogy with the low-energy fission of heavy nuclei as a manifestation of an independent mode of nuclear decay which competes with the classical fusion-fission process.

Published

2003

6. The fission of heated nuclei in reactions involving heavy ions: static and dynamical aspects

Author

A. Ya. Rusanov and M. G. Itkis

Subjects

Physics, Nuclear and High Energy Physics, Range (particle radiation), Angular momentum, Light nucleus, Fission, Nuclear Theory, Ion, Nuclear physics, medicine.anatomical_structure, Excited state, Saddle point, medicine, Atomic physics, Nuclear Experiment, Nucleus

Abstract

The various aspects of the formation of the fragment mass–energy distributions from the fission of excited nuclei in the range Z 2 /A=20–43 in heavy-ion reactions are reviewed. These are: the actual temperature of the fissioning nucleus after the emission of prefission particles, the effect of the angular momentum transferred to the nucleus by the incident ion, the static features of the formation of the fragment distributions of very light nuclei, the role and nature of dynamical effects in the descent of the nucleus from the saddle point to the scission point in the case of heavy nuclei, and the properties of quasi-fission. A fairly complete summary is given of both the experimental data on all these aspects and the theoretical understanding based on current ideas about the fission process.

Published

1998