Site-Specific Reactivity of Ethylene at Distorted Dangling-Bond Configurations on Si(001).

Differences in adsorption and reaction energetics for ethylene on Si(001) are reported with respect to distorted dangling-bond configurations induced by hydrogen precoverage, as obtained by DFT calculations. This can help to understand the influence of surface defects and precoverage on the reactivity of organic molecules on semiconductor surfaces in general. The results show that the reactivity of surface dimers fully enclosed by hydrogen-covered atoms is essentially unchanged compared to the clean surface. This is confirmed by scanning tunneling microscopy measurements. On the contrary, adsorption sites with partially covered surface dimers show a drastic increase in reactivity. This is due to a lowering of the reaction barrier by more than 50 % relative to the clean surface, which is in line with previous experiments. Adsorption on dimers enclosed by molecule (ethylene)-covered surface atoms is reported to have a strongly decreased reactivity, as a result of destabilization of the intermediate state due to steric repulsion; this is quantified through periodic energy decomposition analysis. Furthermore, an approach for the calculation of Gibbs energies of adsorption based on statistical thermodynamics considerations is applied to the system. The results show that the loss in molecular entropy leads to a significant destabilization of adsorption states.

Precursor States of Organic Adsorbates on Semiconductor Surfaces are Chemisorbed and Immobile.

Intermediate states to covalent attachment of molecules on surfaces, so called precursors, are usually considered to be physisorbed and mobile. We show that this view should be reconsidered and provide evidence for a chemisorbed precursor for ethylene on Si(001). The character of the molecule-surface bond as a π complex is determined and quantified using our recently developed method for energy and charge analysis in extended systems. In contrast to previous assumptions, the precursor should thus be immobile, which is underlined by computation of high diffusion energy barriers. This has important implications for understanding and modelling of adsorption kinetics. Our analysis highlights that taking the viewpoint of molecular chemistry helps uncover important aspects in the adsorption process on surfaces. Previous experimental results that appear to be in contrast to our model are examined and reinterpreted.

Pressure dependent mechanistic branching in the formation pathways of secondary organic aerosol from cyclic-alkene gas-phase ozonolysis.

The gas-phase ozonolysis of cyclic-alkenes (1-methyl-cyclohexene, methylene-cyclohexane, α-pinene, ß-pinene) is studied with respect to the pressure dependent formation of secondary organic aerosol (SOA). We find that SOA formation is substantially suppressed at lower pressures for all alkenes under study. The suppression coincides with the formation of ketene (α-pinene, 1-methyl-cyclohexene), ethene (1-methyl-cyclohexene) and the increased formation of CO (all alkenes) at lower reaction pressures. The formation of these products is independent of the presence of an OH scavenger and explained by an increased chemical activation of intermediate species in the hydroperoxide channel after the OH elimination. These findings underline the central role of the hydroperoxide pathway for SOA formation and give insight into the gas-phase ozonolysis mechanism after the stage of the Criegee intermediate chemistry.