Simultaneous tracking of ultrafast surface and gas-phase dynamics in solid–gas interfacial reactions

Real-time detection of intermediate species and final products at the surface and near-surface in interfacial solid–gas reactions is critical for an accurate understanding of heterogeneous reaction mechanisms. In this article, an experimental method that can simultaneously monitor the ultrafast dyna...

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Bibliographic Details
Published in:Review of scientific instruments 2024-08, Vol.95 (8)
Main Authors: Blackman, Keith, Segrest, Eric, Turner, George, Machamer, Kai, Gupta, Aakash, Khan Pathan, Md Afjal, Berriel, S. Novia, Banerjee, Parag, Vaida, Mihai E.
Format: Article
Language:English
Subjects:
Cerium oxides
Gas-solid reactions
Interface reactions
Mass spectra
Mass spectrometry
Reaction mechanisms
Time lag
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Summary:Real-time detection of intermediate species and final products at the surface and near-surface in interfacial solid–gas reactions is critical for an accurate understanding of heterogeneous reaction mechanisms. In this article, an experimental method that can simultaneously monitor the ultrafast dynamics at the surface and above the surface in photoinduced heterogeneous reactions is presented. This method relies on a combination of mass spectrometry and femtosecond pump–probe spectroscopy. As a model system, the photoinduced reaction of methyl iodide on and above a cerium oxide surface is investigated. The species that are simultaneously detected from the surface and gas-phase present distinct features in the mass spectra, such as a sharp peak followed by an adjacent broad shoulder. The sharp peak is attributed to the species detected from the surface, while the broad shoulder is due to the detection of gas-phase species above the surface, as confirmed by multiple experiments. By monitoring the evolution of the sharp peak and broad shoulder as a function of the pump–probe time delay, transient signals are obtained that describe the ultrafast photoinduced reaction dynamics of methyl iodide on the surface and in the gas-phase. Finally, SimION simulations are performed to confirm the origin of the ions produced on the surface and in the gas-phase.
ISSN:0034-6748
1089-7623
1089-7623
DOI:10.1063/5.0217441