Abstract
Recently, hydrogen-fuel cells have attracted attention as an environmentally friendly next-generation energy device. Very recently, biomaterials such as collagen and chitin have realized proton conductivity via water bridges under humidity condition, and the fabrication of fuel cells using biomaterials is possible. However, the fuel cell electrolyte via water has demerits, such as the complication of fuel cell instruments and the operating temperature limit. Therefore, fuel cell electrolytes without humidified conditions are desired. In the present work, we have synthesized an anhydrous proton conductor using imidazole and collagen, which are biomaterials, and investigated the anhydrous proton conductivity in imidazole–collagen composites. It was found that an imidazole–collagen composite is a high-proton conductor above 10−3 S/m and above 200 °C without the humidified condition compared with other anhydrous bio-proton conductors such as the hydroxyapatite–collagen composite. Moreover, the motional narrowing of the 1H-NMR line width reveals that the proton conductivity is realized in the temperature region from 120 to 200 °C. In addition, the DTA measurement and the impedance analyses reveal that the imidazole–collagen composite film undergoes the phase transition at 120 °C. Furthermore, the proton conductivity in the imidazole–collagen composite strongly depends on n, which is the imidazole concentration per collagen molecule and takes a maximum at n = 2.0. In addition, the proton conductivity perpendicular to the collagen fiber is approximately ten times higher than that parallel to the collagen fiber. From these results, it can be deduced that the proton conductivity in the imidazole–collagen composite is caused by breaking and rearranging the hydrogen bonds of the collagen side chain with the imidazole molecule formed between the collagen fibers.
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