6533b7d9fe1ef96bd126c215
RESEARCH PRODUCT
Reversible and Efficient Light-Induced Molecular Switching on an Insulator Surface
Antje RichterAngelika KühnleSimon JaekelStefan HechtLeonhard GrillRobert LindnerRalf BechsteinChristophe Naccisubject
Molecular switchMaterials sciencePhotoisomerizationGeneral EngineeringGeneral Physics and AstronomyInsulator (electricity)02 engineering and technology010402 general chemistry021001 nanoscience & nanotechnology53001 natural sciences0104 chemical sciencesMetalchemistry.chemical_compoundAzobenzenechemistryChemical physicsvisual_artvisual_art.visual_art_mediumMoleculeGeneral Materials Science0210 nano-technologyIsomerizationCis–trans isomerismdescription
Prototypical molecular switches such as azobenzenes exhibit two states, i.e., trans and cis, with different characteristic physical properties. In recent years various derivatives were investigated on metallic surfaces. However, bulk insulators as supporting substrate reveal important advantages since they allow electronic decoupling from the environment, which is key to control the switching properties. Here, we report on the light-induced isomerization of an azobenzene derivative on a bulk insulator surface, in this case calcite (101̅4), studied by atomic force microscopy with submolecular resolution. Surprisingly, cis isomers appear on the surface already directly after preparation, indicating kinetic trapping. The photoisomerization process is reversible, as the use of different light sources results in specific molecular assemblies of each isomer. The process turns out to be very efficient and even comparable to molecules in solution, which we assign to the rather weak molecular interaction with the insulator surface, in contrast to metals.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2018-01-18 | ACS Nano |