Structure of the Majorana’s equation and its physical interpretation

It is generally believed that Majorana’s paper [4] describes particles which have no antiparticles. A thorough analysis have shown that this paper gives rise to the questions the answers to which have not been realized up to now. By the Majorana equation we mean the equation that describes stable, massive, and neutral leptons. Fulfillment of these three requirements leads strictly and unambiguously to the conclusion that the Majorana equation describes a pair of stable, massive, and neutral leptons, a particle and an antiparticle. This is similar to the Dirac equation, but the spin properties of the leptons of this type differ from the spin properties of the electron or positron

Notes on the problems of relativistic nuclear physics

This article presents some arguments in favor of the necessity and opportunity to describe leptons and quarks on the united relativistic basis. The necessity is caused by experimental results of the relativistic nuclear physics. The opportunity has become really attainable taking into account the structure of the lepton equation groups and all their substructures obtained during the latest years

Probing the low and high density nuclear matter by hadron scattering

The subject of this report is connected with the widely discussed manifestation of in-medium effect in nuclear collisions. At present, the medium modification of hadron properties in the normal and in a dense nuclear matter is one of the fundamental questions of strong interaction physics. A new Glauber Monte Carlo model for hadron–nuclei interaction at intermediate energy is proposed. We utilized the principal assumptions as in the approaches of other authors describing nuclear collisions at high energy in the framework of the models without QGP. Yet, a number of new ingredients (noneikonal corrections, correlations of nucleons, in the nuclei, the nuclear Fermi motion, etc.) are introduced

Notes on the problems of relativistic nuclear physics

This article presents some arguments in favor of the necessity and opportunity to describe leptons and quarks on the united relativistic basis. The necessity is caused by experimental results of the relativistic nuclear physics. The opportunity has become really attainable taking into account the structure of the lepton equation groups and all their substructures obtained during the latest years