​Micropore-confined electrochemistry

The slit-shaped micropores have a unique interaction potential profile. These confined spaces afford quasi-high pressures that can induce  physical and chemical properties. Quinone and its derivatives are important redox-active materials, which have been studied as potential electrode materials for various energy storage applications. However, their electrochemical reactions are typically quasi-reversible or irreversible due to the poor electron-transfer kinetics. We recently found that the micropores reportedly play an essential role in obtaining a reversible redox reaction (reversible redox reaction (ΔEp = 0 mV)). In addition, we determined that the AC micropore width required to obtain a reversible redox reaction was in the sub-nanometer scale. Our findings will attract a wide range of readers to your journal as we propose a new technique for the development of useful energy storage devices, and we believe our results will have important implications in the fields of electrochemistry, electronics, energy, and materials science.

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• Daisuke Takimoto*, Keisuke Suzuki, Sho Hideshima, and Wataru Sugimoto, "Origin of the Adsorption-Controlled Redox Behavior of Quinone-Based Molecules: Importance of the Micropore Width", Electrochemistry, 91(7), 077006 (2023). DOI

• ​Daisuke Takimoto*, Keisuke Suzuki, Sho Hideshima, and Wataru Sugimoto, "Confinement Effects on the Rate Performance of Redox Active Molecules for Pseudocapacitive Flowable Electrodes", Electrochemistry, 91(4), 047005 (2023). DOI

• Daisuke Takimoto*,  Keisuke Suzuki,  Ryusuke Futamura,  Taku Iiyama,  Sho Hideshima, and Wataru Sugimot, "Zero-Overpotential Redox Reactions of Quinone-Based Molecules Confined in Carbon Micropores", ACS Applied Materials & Interfaces, 14(27),　31131-31139 (2022). DOI