膜
微型多孔材料
电导率
单体
离子交换
化学工程
体积热力学
聚合物
化学
高分子化学
离子
材料科学
离子运输机
气体分离
肿胀 的
功率密度
电流密度
合成膜
燃料电池
无机化学
动力学
作者
Zhen Li,Jingyi Wu,Weixuan Li,Shiyao Sun,Qianlong Wang,Jialin Zhao,Yijia Lei,Na Li,Jiayao Yang,Yuchao Wang,Zhe Wang
标识
DOI:10.1021/acssuschemeng.5c10330
摘要
Anion exchange membranes (AEMs), as the core component of anion exchange membranes fuel cells (AEMFCs), exhibit high OH – conductivity and dimensional stability, which are critical for continuous and stable power generation. In this paper, the synthesis of 6,6′-dimethoxy-3,3,3′,3′-tetramethyl-1,1′-spirobiindane (SBI) was introduced, and it was synthesized to prepare a series of fluorinated poly(aryl piperidinium) microporous AEMs (QFPTP-SBI- m ). The thermodynamic incompatibility in the polymer drives the formation of the microphase separation structure. The hydrophobic regions can restrict the swelling of the membrane, and the hydrophilic regions serve as ion transport channels. Additionally, the introduction of SBI monomers increases the free volume between the chains and reduces the transport resistance. The synergistic effect of microphase separation and free volume is utilized to regulate the properties of the AEMs. QFPTP-SBI-20% exhibited high OH – conductivity (197.53 mS cm –1 ), and the peak power density (PPD) reached 1.08 W cm –2 at a current density of 2.5 A cm –2 . The WU of 41.36% and SR of 15.99% at 80 °C ensure good dimensional stability. Furthermore, the OH – conductivity was reduced by 8.71% after 1700 h (3 M NaOH). The prepared QFPTP-SBI-20% area exceeded 140 cm 2, indicating its significant potential for large-scale applications.
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