AI Article Synopsis

  • - The study investigates how charge transfer occurs during chemical reactions at metal-organic interfaces, focusing on a self-assembled monolayer (Im-SAM) on gold, using various spectroscopic techniques and theoretical calculations.
  • - Researchers aimed to see if adding atomic hydrogen to the imidazole groups in the Im-SAM would lead to the formation of stable imidazolium cations and promote electron transfer to the gold substrate.
  • - Results showed that hydrogen irradiation resulted in imidazolium cation formation and confirmed changes in work function, indicating successful electron transfer processes despite the insulating layer of alkanethiolate.

Article Abstract

The charge transfer capability associated with chemical reactions at metal-organic interfaces was studied via the atomic H addition reaction for an imidazole-terminated alkanethiolate self-assembled monolayer (Im-SAM) film on Au(111) at room temperature, using near-edge X-ray absorption fine structure spectroscopy, infrared reflection absorption spectroscopy, work function measurements, and density functional theory calculations. The imidazolium cation is a stable species in liquids; therefore, it is pertinent to determine whether the hydrogenation reactions of the imidazole groups produce imidazolium cations accompanied by electron transfer to the Au substrate, even in the absence of solvate and/or counterions on the insulating alkanethiolate layer. The experiments made it clear that the imidazolium moieties were formed during the irradiation of Im-SAM with atomic H. Theoretical model calculations also revealed that the total energies and molecular orbital levels satisfied the imidazolium cation formation associated with electron transfer. In a detailed analysis of the work function change depending on H irradiation, we confirmed that some of the imidazolium radicals became cations in Im-SAM.

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http://dx.doi.org/10.1021/acs.jpclett.4c02306DOI Listing

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