We demonstrate that the matter density distribution in the surface region is determined well by the use of the relatively low-intensity beams that become available at the upcoming radioactive beam facilities. Following the method used in the analyses . . .

We calculate cross sections of high energy electron inclusive scattering off nuclear matter in a new and consistent formulation based on the Green's function method with the Glauber approximation, which is an extension of our previous work on the nucl . . .

We demonstrate that the surface region of the matter density distribution could be determined well even by relatively low intensity beams expected to be available at the upcoming radioactive beam facilities. Our method will allow the practical procedu . . .

Nuclear transparency is calculated for high-energy, semi-inclusive (e, e ? p ) reactions, by accounting for all orders of Glauber multiple-scattering and by using realistic finite-range pN interaction and (dynamically and statistically) correlated nuc . . .

Nuclear transparency is calculated for high-energy, semi-inclusive (e, e′p) reactions, by accounting for all orders of Glauber multiple-scattering and by using realistic finite-range pN interaction and (dynamically and statistically) correlated nuclea . . .

We examine target mass number (A) dependence of the nuclear transparency calculated for (e, e'p) reactions. Generally, the transparency is proportional to A-113 for large A's and has weaker A-dependence as A decreases. The conventional nuclear physics . . .