Cinnamaldehyde adsorption and thermal decomposition on copper surfacesa)

Bo Chen, R. Ponce, J. Guerrero‐Sanchez, N. Takeuchi, F. Zaera
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引用次数: 2

Abstract

The uptake and thermal chemistry of cinnamaldehyde on Cu(110) single-crystal surfaces were characterized by temperature-programmed desorption and x-ray photoelectron spectroscopy (XPS). Adsorption at 85 K appears to be initiated by low-temperature decomposition to form styrene, which desorbs at 190 K, followed by the sequential buildup of a molecular monolayer and then a condensed molecular film. Molecular desorption from the monolayer occurs at 410 K, corresponding to a desorption energy of approximately 98 kJ/mol, and further decomposition to produce styrene (again) and other fragmentation products is seen at 550 K. The molecular nature and the quantitation of the low-temperature uptake were corroborated by the XPS data, which also provided hints about the adsorption geometry adopted by the unsaturated aldehyde on the surface. Density functional theory calculations, used to estimate adsorption energies as a function of coverage and coordination mode, pointed to possible η1-O binding, at least at high coverages, and to a stabilizing effect on the surface by the aromatic ring of cinnamaldehyde. Finally, coadsorption of oxygen on the surface was found to weaken the binding of cinnamaldehyde to the Cu substrate at high coverages without enhancing its uptake, but to not modify the decomposition mechanism or energetics in any significant way.
铜表面对肉桂醛的吸附和热分解
利用程序升温解吸和x射线光电子能谱(XPS)表征了肉桂醛在Cu(110)单晶表面的吸附和热化学性质。85 K时的吸附似乎是由低温分解形成苯乙烯开始的,苯乙烯在190 K时解吸,随后依次形成分子单层,然后是浓缩的分子膜。分子在410 K时发生脱附,对应的脱附能约为98 kJ/mol,在550 K时进一步分解生成苯乙烯(再次)和其他裂解产物。XPS数据证实了低温吸附的分子性质和定量,也为不饱和醛在表面的吸附几何结构提供了线索。密度泛函理论计算用于估计吸附能作为覆盖率和配位模式的函数,指出可能的η - 1- o结合,至少在高覆盖率下,以及肉桂醛的芳香环对表面的稳定作用。最后,氧在表面的共吸附被发现削弱了肉桂醛与Cu底物在高覆盖率上的结合,但没有增强其吸收,但没有显著改变分解机制或能量学。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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