Highly Hydroxide-Conductive Nanostructured Solid Electrolyte via Predesigned Ionic Nanoaggregates

He, GW (He, Guangwei)^[ 1,2 ] ; Xu, MZ (Xu, Mingzhao)^[ 1,2 ] ; Li, ZY (Li, Zongyu)^[ 1,2 ] ; Wang, SF (Wang, Shaofei)^[ 1,2 ] ; Jiang, ST (Jiang, Shentao)^[ 4 ] ; He, XY (He, Xueyi)^[ 1,2 ] ; Zhao, J (Zhao, Jing)^[ 1,2 ] ; Li, Z (Li, Zhen)^[ 1,2 ] ; Wu, XY (Wu, Xingyu)^[ 1,2 ] ; Huang, T (Huang, Tong)^[ 1,2 ] ; Chang, CY (Chang, Chaoyi)^[ 1 ] ; Yang, XL (Yang, Xinlin)^[ 2,3 ] ; Wu, H (Wu, Hong)^[ 1,2 ] ; Jiang, ZY (Jiang, Zhongyi)^[ 1,2 ]

ACS APPLIED MATERIALS & INTERFACES, 2017, 9(34): 28346-28354

DOI: 10.1021/acsami.7b05400

 WOS:000409395500023

Abstract

The creation of interconnected ionic nanoaggregates within solid electrolytes is a crucial yet challenging task for fabricating high-performance alkaline fuel cells. Herein, we present a facile and generic approach to embedding ionic nanoaggregates via predesigned hybrid core shell nanoarchitecture within nonionic polymer membranes as follows: (i) synthesizing core shell nanoparticles composed of SiO2/densely quaternary ammonium-functionalized polystyrene. Because of the spatial confinement effect of the SiO2 "core", the abundant hydroxide-conducting groups are locally aggregated in the functionalized polystyrene "shell", forming ionic nanoaggregates bearing intrinsic continuous ion channels; (ii) embedding these ionic nanoaggregates (20-70 wt %) into the polysulfone matrix to construct interconnected hydroxide-conducting channels. The chemical composition, physical morphology, amount, and distribution of the ionic nanoaggregates are facilely regulated, leading to highly connected ion channels with high effective ion mobility comparable to that of the state-of-the-art Nafion. The resulting membranes display strikingly high hydroxide conductivity (188.1 mS cm(-1) at 80 degrees C), which is one of the highest results to date. The membranes also exhibit good mechanical properties. The independent manipulation of the conduction function and nonconduction function by the ionic nanoaggregates and nonionic polymer matrix, respectively, opens a new avenue, free of microphase separation, for designing high-performance solid electrolytes for diverse application realms.