膜
质子交换膜燃料电池
纳米复合材料
磷酸
材料科学
热稳定性
热重分析
化学工程
电导率
复合材料
高分子化学
化学
物理化学
生物化学
工程类
冶金
作者
N. Nambi Krishnan,Sang‐Rae Lee,Ravindra V. Ghorpade,Anastasiia Konovalova,Jong Hyun Jang,Hyoung‐Juhn Kim,Jonghee Han,Dirk Henkensmeier,Haksoo Han
标识
DOI:10.1016/j.memsci.2018.05.006
摘要
Abstract Crosslinked metal oxide containing nanocomposite membranes, in which the filler also acts as crosslinker, were prepared by blending polybenzimidazole (PBI-OO) and phenylsulfonated TiO2 particles (s-TiO2). Thermal curing changes the ionically crosslinked system into a covalently crosslinked system. The synthesized s-TiO2 nanoparticles were analyzed by thermal gravimetric analysis and scanning electron microscopy. The covalently crosslinked nanocomposite membranes (c-sTiO2-PBI-OO) were doped with phosphoric acid (PA) for high temperature proton exchange membrane fuel cell (HT-PEMFC) application. The membrane properties, such as PA uptake, dimensional change, gel content, proton conductivity, mechanical property, and single cell performance were evaluated and compared with the properties of acid-doped c-PBI-OO. PA doped 6-c-sTiO2-PBI-OO (6 wt% sTiO2) showed the highest uptake of 392 wt%, and a proton conductivity at 160 °C of 98 mS cm−1. In the fuel cell, a peak power density of 356 mW cm−2 was obtained, which is 76% higher than that of a c-PBI-OO based system (202 mW cm−2). To evaluate the stability of the membrane performance over time, the best performing membrane was tested for over 700 h.
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