Abstract
Applying strong direct current (DC) electric fields on the apex of a sharp metallic tip, electrons can be radially emitted from the apex to vacuum. Subsequently, they magnify the nanoscopic information on the apex, which serves as a field emission microscope (FEM). When depositing molecules on such a tip, peculiar electron emission patterns such as clover leaves appear. These phenomena were first observed seventy years ago. However, the source of these emission patterns has not yet been identified owing to the limited experimental information about molecular configurations on a tip. Here, we used fullerene molecules and characterized the molecule-covered tip by an FEM. In addition to the experiments, simulations were performed to obtain optimized molecular configurations on a tip. Both results indicate that the molecules, the source of the peculiar emission patterns, appear on a molecule layer formed on the tip under strong DC electric fields. Furthermore, the simulations revealed that these molecules are mostly isolated single molecules forming single-molecule-terminated protrusions. Upon the excellent agreements in both results, we concluded that each emission pattern originates from a single molecule. Our work should pave the way to revive old-fashioned electron microscopy as a powerful tool for investigating a single molecule.
Highlights
Applying strong direct current (DC) electric fields on the apex of a sharp metallic tip, electrons can be radially emitted from the apex to vacuum
When a single molecule with a size of one nanometre appears on a tip apex, which is spatially separated from the other molecules, the magnification of the field emission microscope (FEM) can be increased by a factor of 20 and the spatial resolution becomes improved to around 3 Å8
After depositing molecules on a tip, different FEM images could be observed depending on the amount of deposited molecules and DC electric fields
Summary
Applying strong direct current (DC) electric fields on the apex of a sharp metallic tip, electrons can be radially emitted from the apex to vacuum. In addition to the experiments, simulations were performed to obtain optimized molecular configurations on a tip Both results indicate that the molecules, the source of the peculiar emission patterns, appear on a molecule layer formed on the tip under strong DC electric fields. It becomes possible to observe at least part of the inner structure of the molecules Together with our FEM experiments, we performed simulations to determine the optimized molecule configurations on a tip under strong DC electric fields, and we aimed to learn about the sources of the emitted electrons. The simulations further revealed that each protrusion is primarily a single molecule, and the protrusion is the potential source of electrons
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