Phase-sensitive detection of electron-beam-induced desorption from ZnO

Abstract

We report a method of phase‐sensitive detection of desorption from surfaces bombarded by a properly modulated electron beam. Mass‐spectrometer signals detected by this method assure a high sensitivity and selectivity of the results. This method is used here for studying surfaces of ZnO powders, and it found that CO₂ is the only desorbed species during electron bombardment of such surfaces. Following the CO₂ desorption kinetics simultaneously with the associated surface conductivity change, we find one‐to‐one correspondence between both quantitites. Furthermore, the rates of the electron‐induced CO₂ desportion and the surface conductivity are in a very good agreement with a theoretical model, previously developed for photodesorption. This model predicts a slowing of the desorption rate due to the buildup of an electron accumulation layer and a corresponding band bending which hinder irradiation‐generated holes from reaching the surface and neutralizing CO⁻₂ species chemisorbed on it. Our observations seem to support this model together with pointing out the similarities between electron‐ and photon‐induced desorption in this case.