Quinone-based
aromatic compounds have been studied as electrode
materials for various energy-storage devices. However, the relatively
large activation barrier of the charge-transfer process of these redox-active
molecules causes sluggish reactions and a decrease in energy efficiency.
To lower the activation barrier, aromatic compounds must be strongly
adsorbed on the electrode surface, preferably via π–π
stacking interactions. Molecules in slit-shaped micropores strongly
adsorb on the graphitic walls, thus experiencing unique micropore-confinement
properties. In this study, the micropore-confinement effect is extended
to the adsorption of quinone-based redox-active molecules in 0.8 nm
slit-shaped micropores of activated carbon, which produces a drastic
reduction in the activation barrier of the charge-transfer process
and creates a zero-overpotential redox reaction. The property originates
from the short distance (approximately 0.3 nm) between the quinone
molecules and the graphitic wall due to the strong adsorption of the
aromatic compound. Our results provide the first demonstration that
the micropore-confinement effect can reduce and nearly eliminate the
activation barrier of an electrochemical reaction. We also demonstrate
the applicability of this approach via the charge/discharge performance
of a two-electrode cell. Cells comprising the aromatic compound/activated
carbon material as positive and negative electrodes exhibit a greater
retention capacity than those without activated carbon. The technique
described herein can guide the development of high-performance, rapid
charging/discharging electrodes for energy-storage devices such as
batteries, supercapacitors, and hybrid devices using organic materials.