Your search keyword '"J. P. Blocki"' showing total 9 results

1. THE INTERNAL EXCITATION OF THE GAS OF INDEPENDENT PARTICLES IN A TIME DEPENDENT POTENTIAL

Author

I. S. Yatsyshyn, A. G. Magner, and J. P. Blocki

Subjects

Physics, Vibration, Nuclear and High Energy Physics, Deformation (mechanics), Quantum gas, Quantum mechanics, Shell (structure), General Physics and Astronomy, Atomic physics, Small amplitude, Legendre polynomials, Excitation

Abstract

The order-to-chaos transition in the dynamics of independent classical and quantum gas of particles was studied by means of the computer simulations within the nuclear model based on the time-dependent mean-field approach. The excitation of the classical gas for containers whose surfaces are rippled according to Legendre polynomials P2, P3 is followed for twenty periods of oscillations. For different vibration frequencies of small amplitude vibrations of such a container near the spherical equilibrium shape we obtained for the classical gas much smaller excitation energies than those predicted by the wall formula. With increasing equilibrium deformation they become significantly larger and for P3 vibrations they are close to the wall formula limit. Notable shell effects were found in the excitation energies of the quantum gas in the Woods-Saxon potential with the corresponding relatively sharp (diffuseness equals to 0.1 fm) moving surfaces for small-amplitude slow vibrations.

Published

2011

2. Surface corrections to the moment of inertia and shell structure in finite Fermi systems

Author

J. P. Blocki, D. V. Gorpinchenko, A. G. Magner, and J. Bartel

Subjects

Physics, Surface (mathematics), Trace (linear algebra), Nuclear Theory, 010308 nuclear & particles physics, Shell (structure), Semiclassical physics, FOS: Physical sciences, Moment of inertia, 01 natural sciences, Nuclear Theory (nucl-th), symbols.namesake, Classical mechanics, Quantum electrodynamics, 0103 physical sciences, symbols, 010306 general physics, Euler's equations, Adiabatic process, Quantum

Abstract

The moment of inertia for nuclear collective rotations is derived within a semiclassical approach based on the Inglis cranking and Strutinsky shell-correction methods, improved by surface corrections within the nonperturbative periodic-orbit theory. For adiabatic (statistical-equilibrium) rotations it was approximated by the generalized rigid-body moment of inertia accounting for the shell corrections of the particle density. An improved phase-space trace formula allows to express the shell components of the moment of inertia more accurately in terms of the free-energy shell correction. Evaluating their ratio within the extended Thomas-Fermi effective-surface approximation, one finds good agreement with the quantum calculations., Comment: 9 pages,4 figures

Published

2015

3. Nuclear asymmetry energy and isovector stiffness within the effective surface approximation

Author

Peter Ring, A. G. Magner, A. A. Vlasenko, and J. P. Blocki

Subjects

Physics, Nuclear and High Energy Physics, Isovector, Nuclear Theory, media_common.quotation_subject, Isoscalar, Binding energy, FOS: Physical sciences, Asymmetry, Surface energy, Nuclear physics, Nuclear Theory (nucl-th), Dipole, Semi-empirical mass formula, Neutron, media_common

Abstract

The isoscalar and isovector particle densities and the surface tension coefficients at the average binding energy are used to derive analytical expressions of the neutron skin thickness and the isovector stiffness of sharp edged proton-neutron asymmetric nuclei. For most Skyrme forces these quantities are significantly larger than the well known ones. Using the analytical isovector surface energy constants in the framework of the hydrodynamical and the Fermi-liquid droplet models the mean energies and the sum rules of the isovector giant dipole resonances are in fair agreement with the experimental data., Comment: 22 pages, 5 figures, 2 tables

Published

2013

4. Chaoticity and shell effects in the nearest-neighbor distributions for an axially-symmetric potential

Author

J. P. Blocki and A. G. Magner

Subjects

Surface (mathematics), Physics, Nuclear and High Energy Physics, Angular momentum, Shell (structure), Poisson distribution, Molecular physics, Projection (linear algebra), k-nearest neighbors algorithm, symbols.namesake, Classical mechanics, symbols, Wigner distribution function, Axial symmetry

Abstract

Statistics of the single-particle levels in a deformed Woods-Saxon potential is analyzed in terms of the Poisson and Wigner nearest-neighbor distributions for several deformations and multipolarities of its surface distortions. We found the significant differences of all the distributions with a fixed value of the angular momentum projection of the particle, more closely to the Wigner distribution, in contrast to the full spectra with Poisson-like behavior. Important shell effects are observed in the nearest neighbor spacing distributions, the larger the smaller deformations of the surface multipolarities.

Published

2012

5. Semiclassical moment of inertia shell-structure within the phase-space approach

Author

A. G. Magner, D V Gorpinchenko, J. P. Blocki, and J. Bartel

Subjects

Physics, Integrable system, Nuclear Theory, Shell (structure), Semiclassical physics, Moment of inertia, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, symbols.namesake, Classical mechanics, Phase space, symbols, Euler's equations, Adiabatic process, Quantum, Mathematical Physics

Abstract

The moment of inertia for nuclear collective rotations is derived within a semiclassical approach based on the cranking model and the Strutinsky shell-correction method by using the non-perturbative periodic-orbit theory in the phase-space variables. This moment of inertia for adiabatic (statistical-equilibrium) rotations can be approximated by the generalized rigid-body moment of inertia accounting for the shell corrections of the particle density. A semiclassical phase-space trace formula allows us to express the shell components of the moment of inertia quite accurately in terms of the free-energy shell corrections for integrable and partially chaotic Fermi systems, which is in good agreement with the corresponding quantum calculations.

Published

2015

6. Derivative corrections to the symmetry energy and the isovector dipole-resonance structure in nuclei

Author

Peter Ring, A. G. Magner, and J. P. Blocki

Subjects

Physics, Nuclear Theory, Isovector, Structure (category theory), FOS: Physical sciences, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Surface energy, Symmetry (physics), Nuclear Theory (nucl-th), Dipole, Energy density, Particle, Atomic physics, Mathematical Physics, Energy (signal processing)

Abstract

The effective surface approximation is extended accounting for derivatives of the symmetry energy density per particle. Using the analytical isovector surface energy constants within the Fermi-liquid droplet model, one obtains energies and sum rules of the isovector dipole resonance structure in a reasonable agreement with the experimental data and other theoretical approaches., Comment: 9 pages, 5 figures, 21st Nuclear Physics Workshop, Kazimierz Dolny, Poland, 23rd-28th September, 2014

Published

2015

7. Isovector dipole-resonance structure within the effective surface approximation

Author

Peter Ring, A. G. Magner, and J. P. Blocki

Subjects

Physics, Surface (mathematics), Nuclear Theory, Isovector, Structure (category theory), FOS: Physical sciences, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Nuclear Theory (nucl-th), Dipole, Transition density, Effective surface, Atomic physics, Constant (mathematics), Nuclear theory, Mathematical Physics

Abstract

The nuclear isovector-dipole strength structure is analyzed in terms of the main and satellite (pygmy) peaks within the Fermi-liquid droplet model. Such a structure is sensitive to the value of the surface symmetry-energy constant obtained analytically for different Skyrme forces in the leptodermous effective surface approximation. Energies, sum rules and transition densities of the main and satellite peaks for specific Skyrme forces are qualitatively in agreement with the experimental data and other theoretical calculations., 6 pages, 2 figures, 1 table

Published

2014

8. Transport coefficients for a slow Fermi-particle motion

Author

A G Magner and J P Blocki

Subjects

Physics, Quantum gas, media_common.quotation_subject, Semiclassical physics, Condensed Matter Physics, Inertia, Conservative vector field, Atomic and Molecular Physics, and Optics, Classical mechanics, Periodic orbits, Multipole expansion, Mathematical Physics, Magnetosphere particle motion, media_common, Fermi Gamma-ray Space Telescope

Abstract

The collective dynamics of a quantum gas of independent particles was studied for a slow collective motion within the nuclear model based on the time-dependent mean-field approach. Leading smooth semiclassical corrections to the friction and inertia coefficients for small multipole distortions of the infinitely deep square-well potential were obtained within the periodic orbit theory. The smooth inertia is mostly larger than its irrotational flow value.

Published

2013

9. GROSS-SHELL EFFECTS IN THE DISSIPATIVE NUCLEAR DYNAMICS

Author

J. P. Blocki, A. G. Magner, and I. S. Yatsyshyn

Subjects

Physics, Nuclear and High Energy Physics, Particle number, Shell (structure), Dissipative system, Nuclear structure, General Physics and Astronomy, Semiclassical physics, Atomic physics, Minimax approximation algorithm, Legendre polynomials, Excitation

Abstract

The order-to-chaos transition in the dynamics of the quantum gas of independent particles was studied within the nuclear model based on the time-dependent mean-field approach. The excitation of the quantum gas in the Woods–Saxon potential with a small diffuseness of its surface rippled according to the Legendre polynomials P2 and P3 are obtained for a slow and small amplitude collective motion. We found strong correlations between time-derivatives of the excitation energies (one-body friction coefficients) and shell-correction energies as functions of the particle number. Semiclassical estimates of the friction coefficients were obtained within the periodic orbit theory by using the uniform approximation.

Published

2012