Functional Materials

Toshio Naito is full professor in the Department of Chemistry and Biology, Graduate School of Science and Engineering, Ehime University, Matsuyama, Japan, since April 2011. He obtained his bachelor’s and master’s degrees and his PhD in physical chemistry from the University of Tokyo, Japan, in 1988, 1990, and 1995, respectively. From April 1990 to March 1995, he worked as a lecturer in the Department of Chemistry, Faculty of Science, Toho University, Tokyo, Japan, and was involved in the development of new molecular metals and superconductors. From April to December 1995, he was assistant professor there, and his research involved the development of new molecular metals and superconductors. From January 1996 to November 2001, he was assistant professor in the Department of Chemistry, Graduate School of Science, Hokkaido University, Sapporo, Japan, working on the development of low-dimensional magnetic conductors. From December 2001 to March 2011, he worked there as associate professor, focusing on time-resolved spectroscopic studies on carrier dynamics of organic magnetic superconductors and the development of new methods of carrier doping for crystalline molecular conductors. Prof. Dr. Naito has received 12 awards, including "The Chemical Society of Japan Award for Creative Work" for 2015 for developing a control method of conduction and magnetism in molecular crystals. He has published 190 research papers and 14 books and has 5 patents to his name. His current research focuses on the development of photoresponsive molecular materials with magnetism, conduction, and other functionalities.

Control of magnetism and conduction in organic materials by light. Diversity in electronic phase due to interchange of MO levels in [M(dmit)2] anion salts M = Pd and Pt. Study of high-temperature oxidation behavior of antimony and bismuth tellurides by thermopiezic analysis and powder x-ray diffraction; a case study of thermochemistry. Organic rechargeable batteries. Development of purely organic superconductors. Multiple-decker metal-porphyrins. Solid oxide fuel cells: electrode materials and membrane formations. Charging up the future by organic solar cells.