Synthesis and guided assembly of niobium trisulfide nanowires and nanowire chains by chemical vapor deposition

TL;DR

This paper presents a scalable chemical vapor deposition method for synthesizing niobium trisulfide nanowires with controlled morphologies and guided assembly on various substrates, enabling potential applications in nanoscale devices.

Contribution

The study introduces a novel CVD process for NbS3 nanowires, demonstrating control over morphology, substrate effects, and guided assembly techniques for 1D transition metal trichalcogenides.

Findings

High growth yield with rates up to 40 μm/min

Two distinct nanowire morphologies achieved

Guided assembly on 2D materials demonstrated

Abstract

One-dimensional (1D) nanostructures of transition metal trichalcogenides (TMT) show unique properties through the combination of their anisotropic bonding and low dimensionality. Scalable synthesis approaches that enable control over the morphology, dimensions, and interfaces of 1D TMTs with other nanoscale materials could allow these properties to be used in novel devices. Here, we report chemical vapor deposition of a 1D TMT, namely niobium trisulfide (NbS3) in the form of nanowires, on different substrates, including bulk substrates (amorphous SiO2/Si and crystalline c-sapphire) and several two-dimensional (2D) van der Waals materials (graphene, h-BN, CrSBr). We demonstrate high growth yield with axial growth rates of up to 40 micrometer/min and with two different growth modes: short nanowires of rectangular cross-section, and unusual long, "chained nanowires" up to 100 micrometer in length with sawtooth morphology. We discuss a mechanism that accounts for the two morphologies and discuss how the structure can be tuned through substrate choice and growth conditions. We further demonstrate guided assembly at the edges of graphene and h-BN, as well as epitaxial growth on few-layer CrSBr and c-sapphire. These results open pathways to explore scalable synthesis and directed assembly of 1D TMT nanomaterials in unique morphologies.