posted on 2021-09-17, 21:03authored byMuthumeenal Arunachalam, Alessandro Sinopoli, Farida Aidoudi, Stephen E. Creager, Rhett Smith, Belabbes Merzougui, Brahim Aïssa
The
deployment of alkaline anion exchange membranes (AEMs) in flow
battery applications has the advantage of a low cationic species crossover
rate. However, the alkaline stability conjugated to the low conductivity
of hydroxide ions of anion exchange membranes (AEMs) still represents
a major drawback for the large deployment of such technology. In this
study, three types of tetraarylpolyphosphonium (pTAP)-based copolymers
(namely, CP1, CP2, and CP3) are synthesized and blended with chitosan
and polyvinylidene fluoride (PVDF) for the fabrication of AEMs. Chitosan,
a green biopolymer, was employed as a blend to enhance the water uptake
of the base ionomer matrix. It is proposed that the abundancy of hydroxyl
groups in chitosan improves considerably the ionic conductivity, water
transport, and ion selectivity of the membrane, together with facilitating
the dispersion of the chitosan in the pTAP copolymer matrix. The purpose
of blending PVDF is instead to provide stable mechanical strength
to the composite blend. The chemical, mechanical, and thermal stabilities
of the three fabricated composite-blend membranes (i.e., CM1, CM2,
and CM3) were characterized. All the membranes exhibited a high water
retaining capacity of up to 36.26% (recorded for CM2) along with a
hydroxyl ion conductivity of 17.39 mS cm–1. Due
to the strong interactions between pTAP copolymers, chitosan, and
PVDF polymers (confirmed also by Fourier transform infrared spectroscopy),
the studied anion exchange membranes are able to retain up to 97%
of the original OH conductivity after 1 M KOH treatment at room temperature
for 100 h. The three membranes, namely, CM1, CM2, and CM3, have vanadium
ion permeabilities measured at 20 °C of 1.775 × 10–8, 1.718 × 10–8, and 1.648 × 10–8 cm2/s, respectively, which are lower than that for the
commercially available Nafion. The good stability and remarkable cell
performance of the composite-blend membranes reported here make them
definitely excellent candidates for the future generation of vanadium
redox flow batteries.