DFT study of superhalogen-doped borophene with enhanced nonlinear optical properties

The concern of the present study is to investigate the nonlinear optical properties of superhalogen-doped borophene owing to its broad applications. The first principle study of the material for its nonlinear optical properties elaborated its use for electrical and optical applications. The superhalogen-based borophene in lithium ion-based batteries and medical appliances have made it one of the most potential materials for optoelectronics. First, hyperpolarizability (beta(o)) of pure and doped B-36 is computed, and the difference between their values was examined. The vertical ionization energy (VIE) was calculated for pure and doped systems. The interaction energy (E-i) for all combinations was computed. It would be expected to be one of the best materials to have high capacity and resistance. For all the calculations and to calculate the highest occupied molecular orbital and lowest unoccupied molecular orbital energy gap, the density functional theory (DFT) method was used. It is predicted that these combinations are more beneficial and can display better nonlinear optical (NLO) properties in electronic devices.

Automated summary

The study investigates the nonlinear optical properties of superhalogen-doped borophene with potential applications in electrical and optical fields. These superhalogen-based borophene materials show promise in lithium ion-based batteries and medical appliances, making them ideal for optoelectronic devices. The use of density functional theory (DFT) methods predicts that these materials can exhibit superior nonlinear optical properties and high capacity and resistance.