Theoretical Evaluation on Inelastic Lepton Scattering of Nuclear Effects.

Abstract

Inelastic scattering is a process in which the kinetic energy of an incident particle is not conserved due to the interaction between an electron and a photon causing an unstable nuclear state. Upon the interaction of the incident photon with matter, Raman scattering occurs where the frequency of the photon shifts towards red or blue. Electron scattering of a profoundly inelastic nature emanating from protons provides the primary evidence for the presence of quarks, neutrons undergo inelastic scattering that excites the nucleus and causes it to emit corpuscular and electromagnetic particles. The aim of this work was to theoretically obtain the nuclear effect on the scattering of inelastic leptons and to observe the nuclear dependence. The methods, cross-section four-momentum transfer squared function and the Lorentz scalar product, were used. The correlation between low energy parameters and quark valence was obtained, the indicative value in quantum chromodynamics is 5% and infinite nuclear material does not lead to any finite size report. The origin of the nuclear effects is not yet evident; however, the structural functions and the effects of finite size were theoretically tested.