Synthesis of Z-scheme (001)-TiO2/Bi5O7I heterojunctions with enhanced interfacial charge separation and photocatalytic degradation of Rhodamine B

“…11 In our previous study, we also verified that constructing heterojunctions can accelerate carrier transfer and improve the degradation efficiency of RhB. 12 Semiconductor materials based on BiOX (X = Cl, Br, I) have been reported with excellent performance. 13,14 Among BiOX photocatalysts, the p-type semiconductor BiOI is very appealing.…”

“…11 In our previous study, we also verified that constructing heterojunctions can accelerate carrier transfer and improve the degradation efficiency of RhB. 12…”

(001)-TiO₂ nanosheets loaded on BiOI improve carrier separation and enhance the photocatalytic activity

“…11 In our previous study, we also verified that constructing heterojunctions can accelerate carrier transfer and improve the degradation efficiency of RhB. 12 Semiconductor materials based on BiOX (X = Cl, Br, I) have been reported with excellent performance. 13,14 Among BiOX photocatalysts, the p-type semiconductor BiOI is very appealing.…”

“…11 In our previous study, we also verified that constructing heterojunctions can accelerate carrier transfer and improve the degradation efficiency of RhB. 12…”

(001)-TiO₂ nanosheets loaded on BiOI improve carrier separation and enhance the photocatalytic activity

“…Consequently, the better photocatalytic effect of the catalyst after Zn 2+ doping may be attributed to the change in bandgap energy. 32 We can calculate the forbidden band of the photocatalyst using the following Kubelka-Munk functional equation:…”

Photocatalytic degradation of RhB in wastewater by zinc ion-doped Bi₅O₇I

TiO₂@BiOCl‐BiOI Heterostructure Photocatalyst for Efficient Removal of Congo Red Dye under Simulated Sunlight