Add to ORKGThe dipole response function of nuclear matter at zero and finite temperatures is investigated by employing the linearized version of the extended TDHF theory with a non-Markovian binary collision term. Calculations are carried out for nuclear dipole vibrations by employing the Steinwedel-Jensen model and compared with experimental results for $^{120}Sn$ and $^{208}Pb$
A systematic study of the damping of the giant dipole resonance (GDR) in 9°Zr, 12°Sn and 2°sPb as a ...
We investigate the collisional damping of giant dipole resonance at finite temperature in the basis ...
International audienceWe perform time-dependent Hartree-Fock (TDHF) calculations, employing Skyrme f...
The dipole response function of nuclear matter at zero and finite temperatures is investigated by em...
We consider the propagation and damping of isovector excitations in heated nuclear matter within the...
The description of collective motion in nuclei at finite temperature using the framework of the rand...
22 Latex pages including 9 figures. Phys. Rev. C (in press)The nuclear collective response at finite...
The nuclear esponse function of 4°Ca is studied at finite temperature using self-consistent RPA. We ...
Abstract We calculate the damping of single-particle motion and of vibrational motion to lowest or...
A detailed derivation of the collisional widths of collective vibrations is presented in both quanta...
The effect of temperature on the evolution of the isovector dipole and isoscalar quadrupole excitati...
A thermal extension of the relativistic nuclear field theory is formulated for the nuclear response....
International audienceIn the present work, the isovector dipole responses, both in the resonance reg...
In the present work, the isovector dipole responses, both in the resonance region and in the low-ene...
The relativistic random phase approximation based on effective Lagrangian with density dependent mes...
A systematic study of the damping of the giant dipole resonance (GDR) in 9°Zr, 12°Sn and 2°sPb as a ...
We investigate the collisional damping of giant dipole resonance at finite temperature in the basis ...
International audienceWe perform time-dependent Hartree-Fock (TDHF) calculations, employing Skyrme f...
The dipole response function of nuclear matter at zero and finite temperatures is investigated by em...
We consider the propagation and damping of isovector excitations in heated nuclear matter within the...
The description of collective motion in nuclei at finite temperature using the framework of the rand...
22 Latex pages including 9 figures. Phys. Rev. C (in press)The nuclear collective response at finite...
The nuclear esponse function of 4°Ca is studied at finite temperature using self-consistent RPA. We ...
Abstract We calculate the damping of single-particle motion and of vibrational motion to lowest or...
A detailed derivation of the collisional widths of collective vibrations is presented in both quanta...
The effect of temperature on the evolution of the isovector dipole and isoscalar quadrupole excitati...
A thermal extension of the relativistic nuclear field theory is formulated for the nuclear response....
International audienceIn the present work, the isovector dipole responses, both in the resonance reg...
In the present work, the isovector dipole responses, both in the resonance region and in the low-ene...
The relativistic random phase approximation based on effective Lagrangian with density dependent mes...
A systematic study of the damping of the giant dipole resonance (GDR) in 9°Zr, 12°Sn and 2°sPb as a ...
We investigate the collisional damping of giant dipole resonance at finite temperature in the basis ...
International audienceWe perform time-dependent Hartree-Fock (TDHF) calculations, employing Skyrme f...