The unique properties of carbon nanotubes (CNTs), such as high strength and stiffness, extremely large specific surface area, low density and high electrical and thermal conductivities, open up opportunities for a wide range of applications. This has led to widespread research on the synthesis of multiscale CNT-based polymeric composites transferring the properties from nanoscale to macroscale. Currently known conventional methods for producing CNT composites rely on dispersing short nanotubes in polymer matrices or infiltrating CNT “buckypaper” with resins. Unlike conventional methods, in this work, super-aligned long CNTs were directly drawn from the vertically aligned CNT arrays and assembled into high volume fraction (~60 vol%) composites. These critical structural features allowed the CNT composites to reach tensile strengths over 1.8 GPa and electrical conductivity ~700-800 S/cm. Thermoplastic and thermosetting polymers were utilized for the fabrication and the results were compared. Our observation suggests that the strengthening and conducting mechanism is derived from the synergistic effect of high degree of CNT alignment, long CNT length, high volume fraction and uniform distribution of CNTs in the polymer matrix produced by spray-winding.
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机译:碳纳米管(CNT)的独特性质,例如高强度和刚度,极大的比表面积,低密度和高电和热导体,为各种应用开辟了机会。这导致了关于将纳米级特性转移到Macroscale的多尺寸CNT的聚合物复合材料的合成的广泛研究。目前已知的用于制备CNT复合材料的常规方法依赖于分散在聚合物基质中的短纳米管或渗透CNT“抗植物”用树脂。与传统方法不同,在该工作中,从垂直对准的CNT阵列直接从垂直对准的CNT阵列中加入超级对准的长CNT,并组装成高容积分数(〜60体积%)复合材料。这些关键结构特征允许CNT复合材料达到超过1.8GPa和电导率〜700-800 s / cm的拉伸强度。热塑性和热固性聚合物用于制造,并比较结果。我们的观察表明,增强和传导机制源自通过喷射绕组产生的聚合物基质中的高度CNT对准,长的CNT长度,高体积分数和CNT的均匀分布来源于加强和传导机制。
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