Electron Transport Properties of Nucleotides Via Nanopore in Stanene Nanoribbon

Nanostructure materials work significantly more effective as sensing channels for designing of FET-based biosensing devices. For FET sensors design, graphene like structure materials are generating scientific interest due to their exceptional characteristics and zero band gap. In the previous decade, important advancements have been developed in the area of solid-state based nanopores, including recent developments in the manufacturing of 2D material-based nanopore sensors. In the current work, we have analyzed the electronic characteristics of a Stanene (Sn)-based nanopore as a investigative study to utilize a Stanene (Sn) nanoribbon for biosensing. Here, first principles theory has been used to investigate the interaction of Adenine (A), thymine (T), cytosine (C), and guanine (G), the four DNA nucleotides (G)-with stanene nanoribbons and calculated findings are reported. In aadition, the application of equilibrium transport theory in the GOLLUM algorithm, has been used to examine the stanene nanoribbons current-voltage graph.