AI Article Synopsis
- The text discusses the synthesis and evaluation of TaPtS, a one-dimensional van der Waals (vdW) material, highlighting its enhanced electrical properties and low dimensionality, suitable for nanomaterial research.
- Spectroscopic and electrical tests reveal that TaPtS has a band gap of 1.18 eV and a work function of 4.77 eV, making it effective in n-type field-effect transistors (FETs) when coupled with chromium (Cr) electrodes.
- The study also demonstrates the creation of p-type FETs using a molybdenum trioxide (MoO) contact and successful fabrication of TaPtS nanowire rectifying diodes, establishing its potential
Article Abstract
Materials with van der Waals (vdW) unit structures rely on weak interunit vdW forces, facilitating physical separation and advancing nanomaterial research with remarkable electrical properties. Recently, there has been growing interest in one-dimensional (1D) vdW materials, celebrated for their advantageous properties, characterized by reduced dimensionality and the absence of dangling bonds. In this context, we synthesize TaPtS, a 1D vdW material, and assess its suitability for field-effect transistor (FET) applications. Spectroscopic analysis and electrical characterization confirmed that the band gap and work function of TaPtS are 1.18 and 4.77 eV, respectively. Leveraging various electrode materials, we fabricated n-type FETs based on TaPtS and identified Cr as the optimal electrode, exhibiting a high mobility of 57 cm V s. In addition, we analyzed the electron transport mechanism in n-type FETs by investigating Schottky barrier height, Schottky barrier tunneling width, and contact resistance. Furthermore, we successfully fabricated p-type operating TaPtS FETs using a molybdenum trioxide (MoO) layer as a high work function contact electrode. Finally, we achieved TaPtS nanowire rectifying diodes by creating a p-n junction with asymmetric contact electrodes of Cr and MoO, demonstrating an ideality factor of 1.06. These findings highlight the electronic properties of TaPtS, positioning it as a promising 1D vdW material for future nanoelectronics and functional vdW-based device applications.
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