Add to ORKGCalculations of nuclear masses, using nuclear density functional theory, are presented for even-even nuclei spanning the nuclear chart. The resulting binding energy differences can be interpreted in terms of valence proton-neutron interactions. These are compared globally, regionally, and locally with empirical values. Overall, excellent agreement is obtained. Discrepancies highlight neglected degrees of freedom and can point to improved density functionals
We perform an analysis of a binding energy difference called δVpn(N,Z)≡-1/4[E(Z,N)-E(Z,N-2)-E(Z-2,N)...
We perform an analysis of a binding energy difference called δVpn(N,Z)≡-1/4[E(Z,N)-E(Z,N-2)-E(Z-2,N)...
The nuclear Energy Density Functional (EDF) approach is used to study medium-mass and heavy nuclei i...
Calculations of nuclear masses, using nuclear density functional theory, are presented for even-even...
To better understand nuclei and the strong nuclear force, it is useful to analyze global nuclear pro...
To better understand nuclei and the strong nuclear force, it is useful to analyze global nuclear pro...
For theoretical nuclear physics to make predictions on nuclei far from stability it is necessary to ...
We study a particular class of relativistic nuclear energy density functionals in which only nucleon...
The foundation of the local energy-density functional method to describe the nuclear ground-state pr...
We study a particular class of relativistic nuclear energy density functionals in which only nucleon...
We show that within the framework of a simple local nuclear energy density functional (EDF), one can...
AbstractA non-relativistic nuclear density functional theory is constructed, not as done most of the...
We perform an analysis of a binding energy difference called δV pn(N,Z)-14[E(Z,N)-E(Z,N-2)-E(Z-2,N)+...
A new version of the Barcelona-Catania-Paris energy functional is applied to a study of nuclear mass...
We perform an analysis of a binding energy difference called δVpn(N,Z)≡-1/4[E(Z,N)-E(Z,N-2)-E(Z-2,N)...
We perform an analysis of a binding energy difference called δVpn(N,Z)≡-1/4[E(Z,N)-E(Z,N-2)-E(Z-2,N)...
We perform an analysis of a binding energy difference called δVpn(N,Z)≡-1/4[E(Z,N)-E(Z,N-2)-E(Z-2,N)...
The nuclear Energy Density Functional (EDF) approach is used to study medium-mass and heavy nuclei i...
Calculations of nuclear masses, using nuclear density functional theory, are presented for even-even...
To better understand nuclei and the strong nuclear force, it is useful to analyze global nuclear pro...
To better understand nuclei and the strong nuclear force, it is useful to analyze global nuclear pro...
For theoretical nuclear physics to make predictions on nuclei far from stability it is necessary to ...
We study a particular class of relativistic nuclear energy density functionals in which only nucleon...
The foundation of the local energy-density functional method to describe the nuclear ground-state pr...
We study a particular class of relativistic nuclear energy density functionals in which only nucleon...
We show that within the framework of a simple local nuclear energy density functional (EDF), one can...
AbstractA non-relativistic nuclear density functional theory is constructed, not as done most of the...
We perform an analysis of a binding energy difference called δV pn(N,Z)-14[E(Z,N)-E(Z,N-2)-E(Z-2,N)+...
A new version of the Barcelona-Catania-Paris energy functional is applied to a study of nuclear mass...
We perform an analysis of a binding energy difference called δVpn(N,Z)≡-1/4[E(Z,N)-E(Z,N-2)-E(Z-2,N)...
We perform an analysis of a binding energy difference called δVpn(N,Z)≡-1/4[E(Z,N)-E(Z,N-2)-E(Z-2,N)...
We perform an analysis of a binding energy difference called δVpn(N,Z)≡-1/4[E(Z,N)-E(Z,N-2)-E(Z-2,N)...
The nuclear Energy Density Functional (EDF) approach is used to study medium-mass and heavy nuclei i...