Abstract In this work, a novel material based on carbon nanostructures (CNS), developed by Applied NanoStructured Solutions, was used with the goal of fabricating scalable CNS-based mats as an alternative to commercially available CNT-based mats. Statistical and experimental methods have been used to determine how the amount of surfactant and the sonication time that is used during fabrication of the mats have affected their mechanical and electrical properties. A strong statistically-significant interaction between surfactant/CNS mass ratio and sonication time was observed. Factorial ANOVA suggested that the combination of a surfactant/CNS mass ratio of approximately 2 and a sonication time of 5 min are optimal for electrical conductivity; this combination used the minimum amount of surfactant and the minimum sonication time of all the values investigated in the study. Samples with combinations of a surfactant/CNS mass ratio of 2 and a sonication time of

中文翻译：

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由排列的 CNT 基薄片制成的高导电性碳纳米结构垫

摘要 在这项工作中，由 Applied NanoStructured Solutions 开发的一种基于碳纳米结构 (CNS) 的新型材料被用于制造可扩展的基于 CNS 的垫子，以替代市售的基于 CNT 的垫子。统计和实验方法已被用于确定表面活性剂的量和在垫的制造过程中使用的超声处理时间如何影响它们的机械和电性能。观察到表面活性剂/CNS 质量比和超声处理时间之间存在强烈的统计学显着性相互作用。因子方差分析表明，表面活性剂/CNS 质量比约为 2 和超声处理时间为 5 分钟的组合对于电导率是最佳的；该组合使用了最少量的表面活性剂，并且在研究中调查的所有值中使用了最短的超声处理时间。表面活性剂/CNS 质量比为 2 且超声处理时间为 2 的样品