2 research outputs found
An Experimental Investigation of the Ion Storage/Transfer Behavior in an Electrical Double-Layer Capacitor by Using Monodisperse Carbon Spheres with Microporous Structure
Monodisperse carbon spheres with coefficient of variation
less than 4% were successfully synthesized through polycondensation
of resorcinol with formaldehyde in the presence of ammonia as a catalyst
followed by carbonization in an inert atmosphere. The diameters of
the carbon spheres can be tuned in the range of 220–1140 nm
by adjusting the ammonia concentration in the precursor solutions.
Although the particle size decreases with increasing ammonia concentrations,
there is no large difference in the internal pore structure between
the different-sized carbon spheres. The size-controlled monodisperse
carbon spheres were used as a model material to understand the ion
storage/transfer behavior in electrical double-layer capacitor (EDLC).
The present study clearly indicates that the reducing the particle
size and highly monodispersity in both size and shape were effective
at reducing mass transport resistance and improving EDLC performance
reliability
Adsorption and Diffusion Phenomena in Crystal Size Engineered ZIF‑8 MOF
ZIF-8
is a flexible zeolitic imidazole-based metal–organic framework
whose narrow pore apertures swing open by reorientation of imidazolate
linkers and expand when probed with guest molecules. This work reports
on the crystal size dependency of both structural transitions induced
by N<sub>2</sub> and Ar adsorption and dynamic adsorption behavior
of <i>n</i>-butanol using well-engineered ZIF-8 crystals
with identical surface area and micropore volume. It is found that
the crystal downsizing of ZIF-8 regulates the structural flexibility
in equilibrium adsorption and desorption of N<sub>2</sub> and Ar.
Adsorption kinetics of <i>n</i>-butanol in ZIF-8 are strongly
affected by the crystal size, however, not according to a classical
intracrystalline diffusion mechanism. Our results suggest that structural
transitions and transport properties are dominated by crystal surface
effects. Crystal downsizing increases the importance of such surface
barriers