Add to ORKGPreliminary ab-initio applications of many-body Green's functions theory to the ground state of He-4 suggest that high accuracy can be achieved in the so-called Faddeev-random-phase-approximation method. We stress the potentialities of this approach for microscopic studies of medium-large nuclei and report applications to 1s0d and 1p0f-shell nuclei. In particular, we discuss the role of long-range correlations on spectroscopic factors and their dependence on asymmetry
We propose a self-consistent quasiparticle random-phase approximation (QRPA) plus quasiparticle-vibr...
In recent years many-body perturbation theory encountered a renaissance in the field of ab initio nu...
The momentum distributions, natural orbits, spectroscopic factors and quasi-hole wave functions of t...
Preliminary ab-initio applications of many-body Green's function theory to the ground state of 4He s...
We consider the proton and neutron quasiparticle orbits around the closed-shell Ni56 and Ca48 isotop...
We review some applications of self-consistent Green's function theory to studies of one- and two-nu...
We review some applications of self-consistent Green's function theory to studies of one- and two-nu...
The Faddeev random phase approximation (FRPA) method is applied to calculate the ground state and io...
International audienceValuable theoretical predictions of nuclear dipole excitations in the whole ch...
Although nuclear energy-density functionals are determined primarily by fitting to ground-state prop...
AbstractSystematic investigation of the accuracy of the description of the energies of deformed one-...
We use the canonical Hartree-Fock-Bogoliubov basis to implement a self-consistent quasiparticle-rand...
This Ph.D. work falls within the scope of theoretical techniques tailored to the solution of the nuc...
We use the quasiparticle random-phase approximation (QRPA) and the Skyrme interactions SLy4 and SkM*...
The spectral function of the closed-shell neon atom is computed by expanding the electron self-energ...
We propose a self-consistent quasiparticle random-phase approximation (QRPA) plus quasiparticle-vibr...
In recent years many-body perturbation theory encountered a renaissance in the field of ab initio nu...
The momentum distributions, natural orbits, spectroscopic factors and quasi-hole wave functions of t...
Preliminary ab-initio applications of many-body Green's function theory to the ground state of 4He s...
We consider the proton and neutron quasiparticle orbits around the closed-shell Ni56 and Ca48 isotop...
We review some applications of self-consistent Green's function theory to studies of one- and two-nu...
We review some applications of self-consistent Green's function theory to studies of one- and two-nu...
The Faddeev random phase approximation (FRPA) method is applied to calculate the ground state and io...
International audienceValuable theoretical predictions of nuclear dipole excitations in the whole ch...
Although nuclear energy-density functionals are determined primarily by fitting to ground-state prop...
AbstractSystematic investigation of the accuracy of the description of the energies of deformed one-...
We use the canonical Hartree-Fock-Bogoliubov basis to implement a self-consistent quasiparticle-rand...
This Ph.D. work falls within the scope of theoretical techniques tailored to the solution of the nuc...
We use the quasiparticle random-phase approximation (QRPA) and the Skyrme interactions SLy4 and SkM*...
The spectral function of the closed-shell neon atom is computed by expanding the electron self-energ...
We propose a self-consistent quasiparticle random-phase approximation (QRPA) plus quasiparticle-vibr...
In recent years many-body perturbation theory encountered a renaissance in the field of ab initio nu...
The momentum distributions, natural orbits, spectroscopic factors and quasi-hole wave functions of t...