The present work describes novel polymer-based nanocomposite anion-exchange membranes (AEMs) with improved features for direct alkaline fuel cell applications. AEMs based on chitosan (CS), magnesium hydroxide (Mg(OH) 2), and graphene oxide (GO) with benzyltrimethylammonium chloride (BTMAC) as the hydroxide conductor were fabricated by a solvent casting method. To impart better mechanical properties and suppressed swelling, the enzymatic cross-linking with dodecyl 3,4,5-trihydroxybenzoate having C-10 alkyl chain was employed. The structure and surface morphology, KOH uptake and swelling ratio, ethanol permeability, mechanical property, ionic conductivity, cell performance, and stability of AEMs were investigated. The as-obtained AEMs showed improved hydroxide conductivity compared with previously reported CS AEMs. The highest value for hydroxide conductivity, 142.5 ± 4.0 mS cm −1 at 40°C, was achieved for the CS + Mg(OH) 2 + GO + BTMAC AEMs with an ethanol permeability value of 6.17 × 10 −7 ± 1.17 × 10 −7 cm 2 s −1 in spite of its relative high KOH uptake (1.43 g KOH/g membrane). The highest peak power density value of 72.7 mW cm −2 was obtained at 209 mA cm −2 when the pristine CS + Mg(OH) 2 AEM was used as the polymer electrolyte membrane in the direct alkaline ethanol fuel cell at 80°C. This is the highest reported power density value for CSbased membranes.
Annealing of C60 in hydrogen
at temperatures above the
stability limit of C–H bonds in C60Hx (500–550 °C) is found to result in direct
collapse of the cage structure, evaporation of light hydrocarbons,
and formation of solid mixture composed of larger hydrocarbons and
few-layered graphene sheets. Only a minor part of this mixture is
soluble; this was analyzed using matrix-assisted laser desorption/ionization
MS, Fourier transform infrared (FTIR), and nuclear magnetic resonance
spectroscopy and found to be a rather complex mixture of hydrocarbon
molecules composed of at least tens of different compounds. The sequence
of most abundant peaks observed in MS, which corresponds to C2H2 mass difference, suggests a stepwise breakup
of the fullerene cage into progressively smaller molecular fragments
edge-terminated by hydrogen. A simple model of hydrogen-driven C60 unzipping is proposed to explain the observed sequence of
fragmentation products. The insoluble part of the product mixture
consists of large planar polycyclic aromatic hydrocarbons, as evidenced
by FTIR and Raman spectroscopy, and some larger sheets composed of
few-layered graphene, as observed by transmission electron microscopy.
Hydrogen annealing of C60 thin films showed a thickness-dependent
results with reaction products significantly different for the thinnest
films compared to bulk powders. Hydrogen annealing of C60 films with the thickness below 10 nm was found to result in formation
of nanosized islands with Raman spectra very similar to the spectra
of coronene oligomers and conductivity typical for graphene.
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