Exploring catalytic efficacy and anti-bacterial performance with molecular docking analysis of g-C3N4-grafted-Ag doped SnO2 QDs

The current work demonstrates the controlled synthesis of graphitic carbon nitride grafted silver (g-C3N4-g-Ag) doped tin oxide (SnO2) quantum dots (QDs) using the co-precipitation method. This research aimed to decrease the charge recombination rate of SnO2 and enhance their multifunctional effectiveness as catalysts and antibacterial agents with molecular docking analysis. The doping of g-C3N4-g-Ag increased the charge separation efficacy and number of active sites, resulting in the enhancement of catalytic and antibacterial activities. 6 mL of g-C3N4-g-Ag doped SnO2 QDs indicated remarkable dye removal activity of over 97.7