Dopants Effect on the Conductive Polymer Performances, Used for Artificial Muscles

2022 IEEE 28th International Symposium for Design and Technology in Electronic Packaging (SIITME) Pub Date : 2022-10-26 DOI:10.1109/SIITME56728.2022.9987743

D. Ionescu, G. Apreotesei

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Abstract

Conductive polymers are good candidates for artificial muscles, considered in microactuators structures with two polymer plates joined by a solid electrolyte. Dopants are essential for the actuating mechanism, considering a oxidation or a reduction process with exchange of anions / cations with the electrolyte. These processes are controlled by different parameters, like the relative diameter of the ions, the used electrolyte and the relative interaction forces solvent-ion, solvent-polymer, polymer-ions and polymer-polymer. For the two classes of dopants, the energy conversion efficiency was calculated based on the data obtained by simulation methods, using the microactuator structure reproduction, with help of the HFSS program (by Ansys). The efficiency can vary between about 20…40%, in function of molar ratios (0.1…0.4) and anions / cations ion radii. These parameters can be optimized analyzing a polyvalent evolution of the efficiency, in function of pairs of correlated parameters, which characterize the structure. Discussion is open in order to choose the practical meaning of the optimizing process, for recommending the optimal conductive polymer composition, used for actuation.

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人造肌肉用掺杂剂对导电聚合物性能的影响

导电聚合物是人造肌肉的良好候选者，在微致动器结构中考虑了由固体电解质连接的两个聚合物板。考虑到与电解质交换阴离子/阳离子的氧化或还原过程，掺杂剂对于驱动机制是必不可少的。这些过程受到不同参数的控制，如离子的相对直径、所使用的电解质以及溶剂-离子、溶剂-聚合物、聚合物-离子和聚合物-聚合物的相对相互作用力。对于两类掺杂剂，基于仿真方法获得的数据，利用微致动器结构再现，借助HFSS程序(Ansys)计算能量转换效率。效率随摩尔比(0.1…0.4)和阴离子/阳离子离子半径的变化在20…40%之间变化。这些参数可以通过分析效率的多价演化来优化，通过对表征结构的相关参数的函数来优化。讨论是为了选择优化工艺的实际意义，为推荐最佳的导电聚合物组成，用于驱动。

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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2022 IEEE 28th International Symposium for Design and Technology in Electronic Packaging (SIITME)

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