Jindong Ren, Mowpriya Das, Yuxiang Gao, Ankita Das, Andreas H Schäfer, Harald Fuchs, Shixuan Du, Frank Glorius
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Scanning tunneling microscopy, electrical conductivity, and scanning electron microscope measurements, as well as density functional theory calculations, were employed to explore the synergistic interactions in the supramolecular SAMs. The van der Waals integration of ballbot-type NHCs and thiols enables the SAMs to exhibit both superior surface anticorrosion properties (attributing to the shift in the <i>d</i>-band center) and low surface resistance originating from the band alignment. Moreover, we find that the deposition sequence of flat-lying NHCs and thiols results in SAMs with different configurations, which can further tune the mechanistic pathway in silico in the acetylene hydrogenation process. 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引用次数: 0
摘要
通过形成自组装单层(SAM)对表面进行修饰,可以有效地设计表面/材料的物理化学特性。然而,如何在分子水平上精确设计多功能 SAM 仍是一大挑战。在这里,我们联合使用了 N-杂环碳烯(NHC)和硫醇来形成多功能杂质 SAM 系统,该系统具有出色的化学稳定性、导电性和催化活性。这种协同效应得益于 NHC 的高表面迁移率和富电子性,以及硫醇的强结合力。我们利用扫描隧道显微镜、电导率和扫描电子显微镜测量以及密度泛函理论计算来探索超分子 SAM 中的协同作用。球机器人型 NHC 与硫醇的范德华整合使 SAMs 不仅具有优异的表面防腐性能(归因于 d 波段中心的偏移),而且由于波段排列而具有较低的表面电阻。此外,我们还发现,平躺的 NHC 和硫醇的沉积顺序会产生不同构型的 SAM,这可以进一步调整乙炔氢化过程的硅学机制路径。我们的研究结果为新 SAM/金属界面的局部电子控制以及新出现的多功能(NHC/硫醇)-SAM 在纳米级形成自组装薄片结构的高稳定性提供了重要的分子见解。
Cooperative Use of N-Heterocyclic Carbenes and Thiols on a Silver Surface: A Synergetic Approach to Surface Modification.
Surface modification through the formation of a self-assembled monolayer (SAM) can effectively engineer the physicochemical properties of the surface/material. However, the precise design of multifunctional SAMs at the molecular level is still a major challenge. Here, we jointly use N-heterocyclic carbenes (NHCs) and thiols to form multifunctional hetero-SAM systems that demonstrate excellent chemical stability, electrical conductivity, and, in silico, catalytic activity. This synergistic effect is facilitated by the high surface mobility and electron-rich nature of NHCs, combined with the strong binding strength of thiols. Scanning tunneling microscopy, electrical conductivity, and scanning electron microscope measurements, as well as density functional theory calculations, were employed to explore the synergistic interactions in the supramolecular SAMs. The van der Waals integration of ballbot-type NHCs and thiols enables the SAMs to exhibit both superior surface anticorrosion properties (attributing to the shift in the d-band center) and low surface resistance originating from the band alignment. Moreover, we find that the deposition sequence of flat-lying NHCs and thiols results in SAMs with different configurations, which can further tune the mechanistic pathway in silico in the acetylene hydrogenation process. Our results provide essential molecular insights into the local electronic control of the new SAM/metal interface and the high stability of the emergent multifunctionality (NHC/thiol)-SAMs forming self-assembled lamellae structures in the nanometer regime.
期刊介绍:
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