| Posted: May 09, 2018 |
Visualization of molecular soccer balls
(Nanowerk News) Fullerenes are composed of 60 carbon atoms joined together in hexagonal rings to form a sphere that strongly resembles a soccer ball. Fullerenes are of great interest to materials scientists because their interesting electronic properties make them attractive for use in advanced electronics and nanotechnology.
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The electronic properties of fullerene can be modified by doping with other elements without altering its soccer ball-like shape. In particular, salts of lithium ion-doped fullerene, which is denoted as Li+@C60, have been synthesized in high yield and the structure of Li+@C60 has been determined. Li+@C60 salts have been used in solar cells and molecular switches with promising results.
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To optimize the performance of Li+@C60 in applications such as photovoltaics and switching devices, it is important to thoroughly understand its electronic properties. An international research collaboration led by the University of Tsukuba recently expanded knowledge of Li+@C60 by managing to image single Li+@C60 molecules by scanning tunneling microscopy. Scanning tunneling microscopy can image materials with molecular-level resolution and provide information about the electronic structure of single molecules.
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![Calculated geometry and charges of Li+C60[PF6-] salt](id50159.jpg) |
| Calculated geometry and charges of Li+@C60[PF6-]salt. (Image: University of Tsukuba)
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The results were published in the journal Carbon ("Electronic structure of Li+@C60: Photoelectron spectroscopy of the Li+@C60[PF6-] salt and STM of the single Li+@C60 molecules on Cu(111)").
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"We fabricated a thin-film sample suitable for scanning tunneling microscopy by vacuum evaporation of a Li+@C60 salt on a copper substrate," study co-author Seiji Sakai explains. "Our subsequent microscopy examination revealed that although some lithium ions escaped during the evaporation process, the sample did contain some Li+@C60 molecules on the copper substrate."
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The microscopy images revealed a mixture of Li+@C60 and undoped fullerene molecules on the copper surface. Both types of molecules were similarly oriented but displayed different heights and electronic structure, allowing them to be differentiated. The team lent further weight to their experimental findings by conducting density functional theory calculations to generate simulated scanning tunneling microscopy images. The experimentally measured and simulated microscopy images agreed well overall.
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"Our study provides confirmation of the electronic structure of lithium-doped fullerene," lead author Yoichi Yamada says. "Such knowledge will aid our ability to modulate the electronic structure of fullerenes to optimize their performance in optoelectronic and switching devices."
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The imaging and electronic structure confirmation of Li+@C60 represent important paving stones on the road to advanced applications of organic materials because they should aid our ability to control the carrier injection and transport properties of fullerenes.
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