Optical Imaging of Chemically and Geometrically Controlled
Interfacial Diffusion and Redox in 2D van der Waals Space
Posted on 22.07.2021 - 09:29
Molecular motions and chemical reactions occurring in constrained space play key roles in many catalysis and energy storage applications. However, its understanding has been impeded by difficulty in detection and lack of reliable model systems. In this work, we report geometric and chemical manipulation of O2 diffusion and ensuing O2-mediated charge transfer (CT) that occur in the 2D space between single-layer transition metal dichalcogenides (TMDs) and dielectric substrates. As a sensitive real-time wide-field imaging signal, charge-density-dependent photoluminescence (PL) from TMDs was used. The two sequential processes inducing spatiotemporal PL change could be drastically accelerated by increasing the interfacial gap size or introducing artificial defects serving as CT reaction centers. We also show that widely varying CT kinetics of four TMDs are rate-determined by the degree of hydration required for the reactions. The reported findings will be instrumental in designing novel functional nanostructures and devices.
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Kang, Haneul; Ryu, Sunmin (1753): Optical Imaging of Chemically and Geometrically Controlled Interfacial Diffusion and Redox in 2D van der Waals Space. ACS Publications. Collection. https://doi.org/10.1021/acs.jpcc.1c04632
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energy storage applicationsgap sizecharge transfercharge-density-dependent photolumin...sequential processesspatiotemporal PL changechemical reactions2 D van der Waals Space Molecular m...single-layer transition metal dicha...Geometrically Controlled Interfacia...dielectric substratesCT reaction centerschemical manipulationTMDOptical ImagingO 2wide-field imaging signalCT kineticsmodel systems2 D spaceO 2 diffusion