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Isotope effect suggests site‐specific nonadiabaticity on Ge(111) <i>c</i> (2×8)

Kerstin Krüger, Yingqi Wang, Lingjun Zhu, Bin Jiang, Hua Guo, Alec M. Wodtke, Oliver Bünermann

2023Natural Sciences13 citationsDOIOpen Access PDF

Abstract

Abstract Energy transferred in atom‐surface collisions typically depends strongly on projectile mass, an effect that can be experimentally detected by isotopic substitution. In this work, we present measurements of inelastic H and D atom scattering from a semiconducting Ge(111) c (2×8) surface exhibiting two scattering channels. The first channel shows the expected isotope effect and is quantitatively reproduced by electronically adiabatic molecular dynamics simulations. The second channel involves electronic excitations of the solid and, surprisingly, exhibits almost no isotope effect. We attribute these observations to scattering dynamics, wherein the likelihood of electronic excitation varies with the impact site engaged in the interaction. Key Points Previous work revealed that H atoms with sufficient translational energy can excite electrons over the band gap of a semiconductor in a surface collision. We studied the isotope effect of the energy transfer by H/D substitution and performed band structure calculations to elucidate the underlying excitation mechanism. Our results suggest a site‐specific mechanism that requires the atom to hit a specific surface site to excite an electron‐hole pair.

Topics & Concepts

Kinetic isotope effectAtomic physicsExcitationScatteringIsotopeAtom (system on chip)ChemistryElectronInelastic scatteringAdiabatic processMolecular physicsPhysicsDeuteriumNuclear physicsOpticsComputer scienceQuantum mechanicsThermodynamicsEmbedded systemAdvanced Chemical Physics StudiesSurface and Thin Film PhenomenaGraphene research and applications