石墨烯纳米片功能化 ZDDP 三膜的摩擦学制造

S Duston, R A Oliver, K J Kubiak, Y Wang, C Wang and A Morina
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摘要

三维三维纳米打印(3D TNP)利用高度可控的摩擦学接触沉积三维薄膜,已被提议作为纳米级结构的制造方法。受此启发,作为概念验证,我们首次展示了对三维薄膜进行电功能化的能力,以用于制造具有纳米级厚度的结构。在生成的二烷基二硫代磷酸锌(ZDDP)三薄膜中加入了不同浓度的石墨烯纳米颗粒(GNPs),从而使其在使用导电原子力显微镜进行测试时具有导电性。在 GNP 浓度最高的情况下,三层薄膜约 55% 的表面能够承受高达 245 pA 临界值的电流。较高的石墨烯含量抑制了薄膜的形成,并降低了基底覆盖率。透射电子显微镜显示了双层三膜,在纯 ZDDP 三膜层上有一层富碳层。在富碳层中,GNPs 形成了卷轴,形成了一个内部网络,电流可以通过该网络流动,但受到薄膜-基底界面上绝缘纯 ZDDP 层以及表面石墨烯片存在的限制。改进的侧向力显微镜程序证实了表面石墨烯片的存在。尽管三维薄膜在均匀性和分布方面的沉积精度有限,但这项工作证明了三维薄膜可以通过添加颗粒添加剂实现功能化,从而为使用三维 TNP 制造纳米级电子结构迈出了一步。
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Tribological manufacturing of ZDDP tribofilms functionalised by graphene nanoplatelets
3D Tribo-Nanoprinting (3D TNP), which uses a highly controllable tribological contact to deposit tribofilms, has been proposed as a manufacturing method for nanoscale structures. Inspired by this, we show for the first time, as a proof of concept, the ability to electrically functionalise tribofilms for potential use in the manufacture of structures with nanoscale thickness. Zinc dialkyldithiophosphate (ZDDP) tribofilms have been generated to include varying concentrations of graphene nanoplatelets (GNPs) resulting in them becoming electrically conductive when tested using conductive atomic force microscopy. In its highest GNP concentration, approximately 55% of the surface of the tribofilm was able to sustain current up to a threshold of 245 pA. The higher graphene content led to a suppression in film formation and decreased substrate coverage. Transmission electron microscopy revealed a dual-layered tribofilm with a carbon-rich layer above a pure layer of ZDDP tribofilm. Within the carbon-rich layer, the GNPs formed into scrolls which created an internal network through which current could flow, being limited by the insulating pure ZDDP layer at the film-substrate interface, and the presence of surface graphene sheets. A modified lateral force microscopy procedure supported the presence of surface graphene sheets. Despite limited deposition precision in terms of homogeneity and distribution of the tribofilms, this work provides a step towards the use of 3D TNP for the manufacture of electronic structures on the nanoscale by proving that tribofilms can be functionalised by the addition of particle additives.
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