Template-free scalable growth of vertically-aligned MoS nanowire array -structural films towards robust superlubricity

Two-dimensional (2D) molybdenum disulfide exhibits a variety of intriguing behaviors depending on its orientation layers. Therefore, developing a template-free atomic layer orientation controllable growth approach is of great importance. Here, we demonstrate scalable, template-free, well-ordered vertically-oriented MoS 2 nanowire arrays (VO-MoS 2 NWAs) embedded in an Ag-MoS 2 matrix, directly grown on various substrates (Si, Al, and stainless steel) via one-step sputtering. In the meta -structured film, vertically-standing few-layered MoS 2 NWAs of almost micron length (∼720 nm) throughout the entire film bulk. While near the surface, MoS 2 lamellae are oriented in parallel, which are beneficial for caging the bonds dangling from the basal planes. Owing to the unique T-type topological characteristics, chemically inert Ag@MoS 2 nano-scrolls (NSCs) and nano-crystalline Ag (nc-Ag) nanoparticles (NPs) are in situ formed under the sliding shear force. Thus, incommensurate contact between (002) basal planes and nc-Ag NPs is observed. As a result, robust superlubricity (friction coefficient μ = 0.0039) under humid ambient conditions is reached. This study offers an unprecedented strategy for controlling the basal plane orientation of 2D transition metal dichalcogenides (TMDCs) via substrate independence, using a one-step solution-free easily scalable process without the need for a template, which promotes the potential applications of 2D TMDCs in solid superlubricity. Well-ordered vertically oriented MoS 2 nanowire arrays meta-structural film was directly grown on various substrates by one-step sputtering. Owing to the unique topological characteristic, robust superlubricity in a humid ambient is reached.