Shunichi Fukuzumi

Electron Transfer


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and the movement of ClO4 provide strong evidence for the generation of the ET state of Acr+–Mes upon photoexcitation. In contrast to the case of Acr+–Mes, no geometrical difference was observed upon photoexcitation of Acr+–Ph, which does not afford the ET state [72].

Illustration of UV–vis spectral change and UV–vis absorption spectra. Inset show images of frozen PhCN solutions of Acr+–Mes before and after photoirradiation. Illustration of the bending of the N-methyl group by photoexcitation accompanied by the rotation and movement of the ClO4 − by the electrostatic interaction with the Mes⋅+ moiety.

      Source: Hoshino et al. 2012 [72]. Reproduced with permission of American Chemical Society.

Illustration of TEMimages of tAlMCM-41 and sAlMCM-41, and reaction scheme of photocatalytic oxygenation of p-xylene with Acr+–Mes and [(tmpa)CuII]2+ incorporated into sAlMCM-41.

      Source: Fukuzumi et al. 2012 [73]. Reproduced with permission of PNAS.

      Nano‐sized charge‐separated molecules can also be obtained by using single‐walled carbon nanotubes (SWNTs) [76], which exhibit excellent chemical and physical properties as revealed by various potential applications [77–81]. Extensive efforts have so far been devoted to assemble electron donor and acceptor molecules on SWNTs [82–88]. However, the fine control of size (i.e. length) of SWNTs remains a formidable challenge, because SWNTs have seamless cylindrical structures made up of a hexagonal carbon network, which leads to the difficulty of solubilization/functionalization without treatment with strong acid or vigorous sonication [89–92]. On the other hand, the cup‐stacked carbon nanotubes (CSCNTs) that consist of cup‐shaped nanocarbon (CNC) units, which stack via van der Waals attractions, have merited special attention from the viewpoint of the conventional carbon nanotube alternatives [93–96]. The tube–tube van der Waals energy between CNCs has been counterbalanced by the thermal or photoinduced electron transfer multi‐electron reduction due to electrostatic repulsion, resulting in the highly dispersible CNCs with size homogeneity [97,98].

      The structure of the CNCs of the CNC–(H2P)n nanohybrids is shown by the TEM in Figure 4.7b, which reveals a CNC with a hollow core along the length of the nanocup with well‐controlled diameter (c. 50 nm) and size (c. 100 nm) [99]. The weight percentage of porphyrins attached to the CNCs was determined by thermogravimetric analysis (TGA) and elemental analysis to be ca. 20% [99]. This corresponds to one functional group per 640 carbon atoms of the nanocup framework for CNC–(H2P)n nanohybrid. Thus, the π‐framework of the CNC is not destroyed despite attachment of a large number of porphyrin molecules on the CNC.

      Spectroscopic evidence for the covalent functionalization of CNC–(H2P)n nanohybrid was obtained by an intensity increase of the Raman signal at 1353 cm−1 (D band) in the functionalized CNC as compared with the pristine