Neutralization of low energy Na+ scattered from InAs(001)

Abstract

The neutralization probability of low energy Na+ ions scattered from In- and As-rich InAs(001) surfaces is measured by time-of-flight spectroscopy. It is found that the neutralization probability for projectiles scattered from As sites is larger than from In sites for both types of surfaces. A modification of the resonant charge transfer model is proposed in which a freezing contour that follows the atomic structure is combined with molecular dynamics and density functional theory. Together, these approaches show that the neutralization of alkali projectiles scattered from a compound solid material is determined by multiple factors, particularly the surface atomic and electronic structures. This model is applicable to any system in which the surface potential is inhomogeneous, such as compound materials and adsorbate-covered surfaces.