Enhanced photocatalytic degradation of tetracycline hydrochloride by Ag/AgI/WO₃·H₂O composites

Abstract: Novel visible light response Z-scheme Ag/AgI/WO 3 ÁH 2 O composite photocatalysts were synthesized using a two-step hydrothermal method followed by a photoreduction process without adding any surfactant. The synthesized Ag/AgI/WO 3 ÁH 2 O composite (AAW-2) with the Ag/WO 3 ÁH 2 O molar ratio of 0.8/1 showed the highest photodegradation activity for tetracycline hydrochloride (TCH) solution under visible light, and its rate constant was 24.6 times higher than that of WO 3 ÁH 2 O. The enhanced photocatalytic act… Show more

“…[ 3 ] AOPs are based on the generation of highly reactive but less selective hydroxyl and intermediate radicals by ozonation, electrochemical processes, Fenton or photo Fenton, photolysis, and semiconductor photocatalysis. [ 6 ] Among these various AOPs, semiconductor photocatalysis requiring an oxidizing agent, a photon energy source, and a photosensitive surface is widely reported for the degradation of organic pollutants including antibiotic waste. [ 6–8 ] The rate of photocatalytic degradation is also high.…”

“…[ 6 ] Among these various AOPs, semiconductor photocatalysis requiring an oxidizing agent, a photon energy source, and a photosensitive surface is widely reported for the degradation of organic pollutants including antibiotic waste. [ 6–8 ] The rate of photocatalytic degradation is also high. Bi 2 WO 6 nanosheets showed 90.39% degradation of TC under visible light irradiation.…”

“…[ 9 ] Ag/AgI/WO 3 ·H 2 O composites showed enhanced degradation of TC. [ 6 ] These inorganic photocatalysts have several limitations such as the requirement of expensive centrifugation and drying for recovery of the photocatalysts after use. To overcome these limitations activated carbon, [ 10 ] glass [ 11 ] or polymeric materials [ 12 ] are used as support materials.…”

Adsorption and photocatalytic degradation of tetracycline from water by kappa‐carrageenan and iron oxide nanoparticle‐filled poly (acrylonitrile‐co‐N‐vinyl pyrrolidone) composite gel

“…[ 3 ] AOPs are based on the generation of highly reactive but less selective hydroxyl and intermediate radicals by ozonation, electrochemical processes, Fenton or photo Fenton, photolysis, and semiconductor photocatalysis. [ 6 ] Among these various AOPs, semiconductor photocatalysis requiring an oxidizing agent, a photon energy source, and a photosensitive surface is widely reported for the degradation of organic pollutants including antibiotic waste. [ 6–8 ] The rate of photocatalytic degradation is also high.…”

“…[ 6 ] Among these various AOPs, semiconductor photocatalysis requiring an oxidizing agent, a photon energy source, and a photosensitive surface is widely reported for the degradation of organic pollutants including antibiotic waste. [ 6–8 ] The rate of photocatalytic degradation is also high. Bi 2 WO 6 nanosheets showed 90.39% degradation of TC under visible light irradiation.…”

“…[ 9 ] Ag/AgI/WO 3 ·H 2 O composites showed enhanced degradation of TC. [ 6 ] These inorganic photocatalysts have several limitations such as the requirement of expensive centrifugation and drying for recovery of the photocatalysts after use. To overcome these limitations activated carbon, [ 10 ] glass [ 11 ] or polymeric materials [ 12 ] are used as support materials.…”

Adsorption and photocatalytic degradation of tetracycline from water by kappa‐carrageenan and iron oxide nanoparticle‐filled poly (acrylonitrile‐co‐N‐vinyl pyrrolidone) composite gel

Fabrication of mesoporous titania films and kinetics of photoelectrocatalytic degradation of organic dye

WO3·nH2O-based photocatalysts: Structural analysis, rational design, and applications in energy conversion and environmental remediation