Yadav, A.K.Shreevathsa, N.S.Singh, R.Das, P.P.Garg, V.Pandey, S.K.2026-02-042024IEEE Transactions on Nanotechnology, 2024, 23, , pp. 132-1381536125Xhttps://doi.org/10.1109/TNANO.2024.3358017https://idr.nitk.ac.in/handle/123456789/21460Using density functional theory calculations, we demonstrate the quantum capacitance of the VS<inf>2</inf> electrode which can be improved by doping with non-metallic elements such as nitrogen (N), phosphorus (P), and arsenic (As) atoms. The radius, charge, and morphology of these non-metallic elements help to improve the performance of VS<inf>2</inf> material as electrodes of supercapacitors. The As-doped VS<inf>2</inf> monolayer demonstrated the maximum quantum capacitance of 31.2369 μF/cm2 at 300 K. At 1200 K, quantum capacitance reaches the value of 25.2149 μF/cm2, showing the inconsiderable change in value for this wide range of temperature variation. Additionally, the other important properties of undoped and doped VS<inf>2</inf> monolayers such as density of states, energy band structure, electrical conductivity, thermal conductivity, and the Seebeck coefficient were also computed and examined in detail. The band structure of the P and As-doped VS<inf>2</inf> monolayers showed a metallic nature, which is suitable for electrode application. In the case of As-doped VS<inf>2</inf> material, a high figure of merit of 3.536 was observed by using DFT-D2 calculations, due to the large Seebeck coefficient and significant electrical conductivity. Our findings will be helpful in further exploring the suitability of VS<inf>2</inf> monolayers as electrodes of supercapacitors. © 2002-2012 IEEE.Band structureCapacitanceElectric conductivityElectrodesLattice theoryMonolayersSeebeck coefficientSulfur compoundsSupercapacitorThermal conductivityVanadium compounds>)ConductivityDensity-functional-theoryLatticeQuantum capacitanceVanadium disulphide (VS<sub xmlns:ali="Xmlns:mml="Xmlns:xlink="Xmlns:xsi="Density functional theory