Mechanisms of Auger-induced chemistry derived from wave packet dynamics
Julius T. Su, William A. Goddard III
Abstract
To understand how core ionization and subsequent Auger decay lead to bond breaking in large systems, we simulate the wave packet dynamics of electrons in the hydrogenated diamond nanoparticle C_(197)H_(112). We find that surface core ionizations cause emission of carbon fragments and protons through a direct Auger mechanism, whereas deeper core ionizations cause hydrides to be emitted from the surface via remote heating, consistent with results from photon-stimulated desorption experiments [Hoffman A, Laikhtman A, (2006) J Phys Condens Mater 18:S1517–S1546]. This demonstrates that it is feasible to study the chemistry of highly excited large-scale systems using simulation and analysis tools comparable in simplicity to those used for classical molecular dynamics.
Group Members
Su, J. T. & III, W. A. G. (2009). Mechanisms of Auger-induced chemistry derived from wave packet dynamics. *Proc. Natl. Acad. Sci. U.S.A.*, *106*(4), 1001-1005. https://doi.org/10.1073/pnas.0812087106