The mass of the nucleus, through its binding energy, continues to be of capital importance not only for various aspects of nuclear physics, but also for other branches of physics, notably weak-interaction studies and astrophysics. The authors first describe the modern experimental techniques dedicated to the particularly challenging task of measuring the mass of exotic nuclides and make detailed comparisons. Though tremendous progress in these and the associated production techniques has been made, allowing access to nuclides very far from stability, it is still not yet possible to produce many nuclides involved in stellar nucleosynthesis, especially the $r$ process, leaving no choice but to resort to theory. The review thus goes on to describe and critically compare the various modern mass formulas that may be used to extrapolate from the data towards the neutron drip line. Special attention is devoted to the crucial interplay between theory and experiment, showing how new measurements far from stability can considerably reduce the ambiguity in extrapolations to nuclides even further away.

Recent trends in the determination of nuclear masses

Energy levels of light nuclei A = 16-17

Further explorations of Skyrme-Hartree-Fock-Bogoliubov mass formulas. IV: Neutron-matter constraint

In this work, the theory presented in part 1 for an experimental configuration that provides a means to isolate surface coverage measurements by SHG from coverage-dependent molecular orientation changes was tested. The adsorption isotherm for disperse red 1 on glass was found to be quite sensitive to the choice of excitation polarization rotation angle due to a coverage-dependent change in molecular orientation. Appropriate selection of the polarization rotation angle, as dictated by the theory presented in part 1, yielded reliable adsorption isotherm results that were essentially independent of changes in molecular orientation. Use of a standard experimental approach (e.g., probing the intensity of p-polarized second harmonic for p-polarized fundamental), resulted in large error (nearly 100%) in the calculated equilibrium constant. The adsorption isotherm for rhodamine 6G on glass was found to be relatively insensitive to the choice of polarization rotation angle since its apparent orientation angle did not change significantly as a function of coverage.

Orientation-insensitive methodology for second harmonic generation. 2. Application to adsorption isotherm and kinetics measurements

Angular momentum transfer in 12C-, 20Ne- and 40Ar-induced fission

The random exchange of nucleons is seen to play a major role in the misalignment of angular momentum in heavy-ion collisions. It is further found that incorporation of Pauli blocking is very important for a quantitative explanation of the experimental data.

Role of Stochastic Transfer of Nucleons for Angular Momentum Misalignment in Nuclear Collisions

Energy dependent nucleus-nucleus potential in heavy ion collisions

The effect of the shell gap in strongly damped collisions

Vacuum polarization and the nuclear mass formula

It is demonstrated that in the stochastic nucleon exchange model the accumulated spins of the reacting nuclei are nearly parallel for peripheral collisions in the absence of the internuclear barrier; the barrier destroys this strong correlation between the spin orientations. The individual spin directions are, however, insensitive to the barrier.

http://iopscience.iop.org/0305-4616/13/10/002/pdf/0305-4616_13_10_002.pdf

J.N. De

Papers

Role of Stochastic Transfer of Nucleons for Angular Momentum Misalignment in Nuclear Collisions

Energy dependent nucleus-nucleus potential in heavy ion collisions

The effect of the shell gap in strongly damped collisions

Vacuum polarization and the nuclear mass formula

Role of barrier on spin orientation in nucleus-nucleus collisions