Başar Ca̧ǧlarM. Oluş ÖzbekJ. W.Hans NiemantsverdrietC. J. Weststrate2025-10-06201614639084, 146390761463-90761463-908410.1039/c6cp06069bhttps://www.scopus.com/inward/record.uri?eid=2-s2.0-84994344854&doi=10.1039%2Fc6cp06069b&partnerID=40&md5=a7c8acdcbe4ed7313c10887041542623https://gcris.yasar.edu.tr/handle/123456789/9746The adsorption and decomposition of ethanol on Rh(100) was studied as a model reaction to understand the role of C-OH functionalities in the surface chemistry of biomass-derived molecules. A combination of experimental surface science and computational techniques was used: (i) temperature programmed reaction spectroscopy (TPRS) reflection absorption infrared spectroscopy (RAIRS) work function measurements (Kelvin Probe-KP) and density functional theory (DFT). Ethanol produces ethoxy (CH<inf>3</inf>CH<inf>2</inf>O) species via O-H bond breaking upon adsorption at 100 K. Ethoxy decomposition proceeds differently depending on the surface coverage. At low coverage the decomposition of ethoxy species occurs via β-C-H cleavage which leads to an oxometallacycle (OMC) intermediate. Decomposition of the OMC scissions (at 180-320 K) ultimately produces CO H<inf>2</inf> and surface carbon. At high coverage along with the pathway observed in the low coverage case a second pathway occurs around 140-200 K which produces an acetaldehyde intermediate via α-C-H cleavage. Further decomposition of acetaldehyde produces CH<inf>4</inf> CO H<inf>2</inf> and surface carbon. However even at high coverage this is a minor pathway and methane selectivity is 10% at saturation coverage. The results suggests that biomass-derived oxygenates which contain an alkyl group react on the Rh(100) surface to produce synthesis gas (CO and H<inf>2</inf>) surface carbon and small hydrocarbons due to the high dehydrogenation and C-C bond scission activity of Rh(100). © 2017 Elsevier B.V. All rights reserved.EnglishArticle