The stopping power of heavy ions for energies below 0.2 MeV/nucleon measured by the semi-thick target method

“…The transfers of the energy are divided on two parts: (i) the inelastic collisions constitute the principal mode of energy loss; it acted of exchange of loads between the projectile and target atoms, of an ionization of the target atoms or excitation of the electrons [13][14][15][16] and (ii) the elastic collisions result primarily by displacements of the target atoms and thus in crystalline defects in the structure [7]. The stopping power of heavy charged particles at low energy using the semi-thick target method is described in detail in the literature [17].…”

Nuclear Energy Loss and Range of Heavy Ions in SiO2, LiF and Kapton Polyatomic Targets: A Monte Carlo study

“…The transfers of the energy are divided on two parts: (i) the inelastic collisions constitute the principal mode of energy loss; it acted of exchange of loads between the projectile and target atoms, of an ionization of the target atoms or excitation of the electrons [13][14][15][16] and (ii) the elastic collisions result primarily by displacements of the target atoms and thus in crystalline defects in the structure [7]. The stopping power of heavy charged particles at low energy using the semi-thick target method is described in detail in the literature [17].…”

Nuclear Energy Loss and Range of Heavy Ions in SiO2, LiF and Kapton Polyatomic Targets: A Monte Carlo study