Multifunctional structural polymer electrolytes via interpenetrating truss structures

Q1 Materials Science

Multifunctional Materials Pub Date : 2018-11-30 DOI:10.1088/2399-7532/aaee16

I. R. Beringer, M. Walter, J. Snyder, E. Wetzel

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引用次数: 8

Abstract

Multifunctional structures such as mechanical load-bearing batteries and supercapacitors require electrolytes that possess both mechanical robustness and high ionic conductivity. In this study, we use additive manufacturing to build three-dimensional interpenetrating structures as model systems for structural electrolytes. Maxwell truss structures with varying solid volume fractions were fabricated by printing thermoplastic molds using fused filament fabrication, injecting and curing epoxy resins, and then etching away the mold. These unit cells were then subject to uniaxial compression to characterize mechanical stiffness, and intercalated with liquid electrolyte with a form-fitting test cell to measure system ionic conductivity. Finite element simulations of the truss structures provide good agreement with the experimental data, and are then used to calculate shear properties that would be difficult to measure experimentally. The results show that the present truss systems provide superior multifunctional properties compared to prior structural polymer electrolyte systems, and suggest that segregated truss structures are a promising approach for creating multifunctional systems.

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通过互穿桁架结构的多功能结构聚合物电解质

机械承载电池和超级电容器等多功能结构需要兼具机械稳健性和高离子导电性的电解质。在这项研究中，我们使用增材制造来构建三维互穿结构作为结构电解质的模型系统。采用熔融长丝制造、注入和固化环氧树脂，然后蚀刻模具，打印热塑性模具，制造出具有不同固体体积分数的Maxwell桁架结构。然后对这些单体电池进行单轴压缩，以表征机械刚度，并将其与液体电解质嵌套在一起，以测量系统的离子电导率。桁架结构的有限元模拟与实验数据吻合较好，可用于计算难以在实验中测量的抗剪性能。结果表明，与现有结构聚合物电解质体系相比，目前的桁架体系具有优越的多功能性能，并表明分离桁架结构是一种很有前途的多功能体系创建方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Multifunctional Materials Materials Science-Materials Science (miscellaneous)

CiteScore

12.80

自引率

0.00%

发文量