Nano-Scale Wettability of Free-Standing Capped Carbon Nanotube Arrays

Miray Ouzounian, Travis Shihao Hu
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Abstract

Countless organisms in nature have adapted high-aspect-ratio micro-/nano-fibrillar arrays on their functional surfaces for achieving special and often optimized functionalities using earthly abundant materials. At the core of nanoscience and nanotechnology, rationally mimicking nature offers a promising route to create multifunctional superstructures that capture organisms and biological materials’ intriguing responsive and self-adjusting properties. Prior work has demonstrated that hierarchical vertically aligned multi-walled carbon nanotube (VA-MCNT) arrays can achieve ten folds of adhesive force comparing to the fibrillar structures of the gecko toe pads. However, little is known with regard to their wettability at the ultimate atomistic level, and how this may influence the adhesive performance and/or self-cleaning capabilities, despite water condensation and bridging are common phenomena at this length scale. In present study, molecular dynamics (MD) simulations were performed using Large-Scale Atomic / Molecular Massively Parallel Simulator (LAMMPS). Results indicate that commonly believed hydrophobic defect free CNTs (i.e., carbon sp2 hybridization without any dangling bonds) become super-hydrophilic at this length/temporal scale. The critical factors that influence the number of H-Bonds in water are: i) tube-tube spacing; and ii) shape/size and position of the water nanodroplet; and iii) how many droplets exists and how many nanotubes are bridged by the droplets. Chirality has little effect on the water interfacial behaviors. Future work will focus on the effect of water condensation and bridging on the adhesive and self-cleaning properties of carbon-based bio-inspired fibrillar dry adhesives considering defects and saline water.
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独立帽状碳纳米管阵列的纳米尺度润湿性
自然界中无数的生物已经在它们的功能表面上采用了高纵横比的微/纳米纤维阵列,以利用地球上丰富的材料实现特殊的、通常是优化的功能。在纳米科学和纳米技术的核心,合理地模仿自然为创造多功能上层结构提供了一条有希望的途径,这些上层结构可以捕捉生物体和生物材料的有趣的响应和自我调节特性。先前的研究表明,与壁虎趾垫的纤维结构相比,分层垂直排列的多壁碳纳米管(VA-MCNT)阵列可以获得十倍的粘附力。然而,关于它们在最终原子水平上的润湿性,以及这可能如何影响粘合剂性能和/或自清洁能力,知之甚少,尽管水凝结和桥接是这种长度尺度上的常见现象。本研究采用大规模原子/分子大规模并行模拟器(LAMMPS)进行分子动力学模拟。结果表明,通常认为无疏水缺陷的碳纳米管(即没有悬空键的碳sp2杂化)在这个长度/时间尺度上变得超亲水。影响水中氢键数目的关键因素有:1)管间距;(ii)纳米水滴的形状/大小和位置;iii)有多少液滴存在,有多少纳米管被液滴桥接。手性对水界面行为影响不大。未来的工作将集中在考虑缺陷和盐水的情况下,研究水的凝结和桥接对碳基仿生纤维干胶的粘接和自清洁性能的影响。
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