Elucidating the chemical pathways responsible for the sooting tendency of 1 and 2-phenylethanol

Yield Sooting Index (YSI) measurements have shown that oxygenated aromatic compounds (OACs) tend to have lower YSI than aromatic hydrocarbon (AHC) compounds. For example, typical AHCs such as toluene and ethyl benzene have a YSI of 170 and 216, respectively, in contrast, OACs such as phenol and anisole have a YSI of 81 and 111, respectively. However, this trend is not always true as was observed for the structural isomers 1-phenylethanol (1PE, YSI = 142) and 2-phenylethanol (2PE, YSI = 207), where 2PE contains a YSI more representative of AHCs than OACs. We applied flow reactor experiments and density functional theory (DFT) calculations to examine how oxygen functionality present in 1PE and 2PE alters the reaction pathways leading to the observed difference in soot formation. It was determined that the proximity of the oxygen functional group to the aromatic ring determines whether the oxygen remains attached to the primary reacting species (for 1PE) or is eliminated early in the combustion sequence (for 2PE). For these alcohols, preservation of the oxygen in the molecule leads to further OACs, while loss of the oxygen leads to AHCs and benzyl radical. The direct pathways to AHCs and benzyl radical result in the higher YSI observed for 2PE. Published by Elsevier Inc. on behalf of The Combustion Institute.

Automated summary

Oxygenated aromatic compounds (OACs) tend to have lower Yield Sooting Index (YSI) than aromatic hydrocarbon (AHC) compounds, but the proximity of oxygen functionality to the aromatic ring determines the reaction pathways and influences the observed difference in soot formation for structural isomers like 1-phenylethanol and 2-phenylethanol.