Radiation damage in SiO2/Si induced by low-energy electrons via plasmon excitation

Abstract

We have found definite evidence which proves that radiation damage in SiO₂/Si induced by low‐energy electrons is caused by plasmon excitation in SiO₂. The SiO₂/Si sample was irradiated by accelerated thermoelectrons, and the flat‐band voltage shift, ΔV_FB, of the sample was measured by the C‐V method. The effective charge generation yield, R_f, in SiO₂/Si was evaluated from the ΔV_FB and the electron dose. The effective positive charges were measured in p‐type SiO₂/Si, and the effective negative charges were measured in n‐type SiO₂/Si. This is because interface states behave like positive charges in p‐type SiO₂/Si and negative charges in n‐type SiO₂/Si. The R_f in p‐type SiO₂/Si oscillated as a function of the incident electron energy of 5–150 eV with several clear peaks. These peaks correspond to the quantum energy of a bulk plasmon or a surface plasmon. Both plasmons decay into electron‐hole pairs. The holes that escape from recombination with the electrons are trapped at the SiO₂/Si interface and cause effective positive charges. The R_f was maximum when the SiO₂ thickness was 20 nm, independent of the incident electron energy. This is because the plasmon region extends to about 20 nm in SiO₂, and the hole‐trapping efficiency is expected to be maximum at a SiO₂ thickness of 20 nm.