Catalyst | Synthetic method | Conditions for Fenton-like reaction | Catlayst dosage | H2O2 dosage | Pollutants and degradation efficiency | ref |
---|---|---|---|---|---|---|
ZnFe2O4 | hydrothermal route | 150 W Xe lamp | 0.5 g/L | 12.0 mM | AOII 100% (2 h) | |
ZnFe2O4/ graphene | solvothermal method | 500 W Xe lamp | 1.0 g/L | 30% H2O2 (1 mL) | RhB 100% (2 h); MO 96% (2 h) | |
porous C/ZnFe2O4 | CO2-mediated ethanol route | 300 W Xe lamp | 1.0 g/L | 30% H2O2 (2 mL) | RhB 100% (1 h); phenol 91% (2 h) | |
NiFe2O4 | co-precipitation method | - | 2.0 g/L | 120.0 mM | phenol 95% (5.5 h) | |
NiFe2O4/C | calcination method | 800 W Xe lamp | 0.1 g/L | 30% H2O2 (0.1 mL) | TC 97.25% (1 h) | |
NiFe2O4/CNTs | hydrothermal route | 150 W Xe lamp | 0.025 g/L | 1 μL/mL | SMX 90% (2 h) | |
CoFe2O4 | co-precipitation route | 125 W Hg lamp | 1.0 g/L | 30% H2O2 (3 mL) | MB 90% (1.25 h) | |
CoFe2O4-rGO | liquid assembly method | ultrasonic irradiation | 0.08 g/L | 3 mM | AO7 90.5% (2 h) | |
rGO/CoFe2O4 | solvothermal method | 5.0 mmol/l NH2OH | 0.1 g/L | 3 mM | MB 100% (0.25 h) | |
CoFe2O4@PPy | oxidization polymerization | 300 W Xe lamp | 0.2 g/L | 30% H2O2 (200 μL) | RhB 100% (2 h) | |
MnFe2O4 | sol-gel method | - | 0.6 g/L | 200 mM | NOR 90.6% (3 h) | |
MnFe2O4/ biochar | co-precipitation method | 300 W Xe lamp | 0.5 g/L | 200 mM | TC 95% (2 h) | |
MnFe2O4@SnS2 | hydrothermal method | 300 W Xe lamp | 0.2 g/L | 30% H2O2 (3 mL) | MB 92% (2 h) | |
CuFe2O4 | nanocasting strategy | - | 0.3 g/L | 40 mM | Imidacloprid 100% (5 h) | |
Cu/CuFe2O4 | solvothermal method | - | 0.1 g/L | 15 mM | MB 99% (4 min) | |
CuFe2O4@C | solvothermal route | 300 W Xe lamp | 0.1 g/L | 30% H2O2 (0.2 mL) | MB 97% (1.5 h) | |
CuFe2O4/rGO | hydrothermal method | 500 W of microwave power | 0.3 g/L | 30% H2O2 (600 μL) | RhB 95.5% (1 min) | |
CuFe2O4@PDA | self-polymerization | - | 0.2 g/L | 0.5 M | MB 97% (0.5 h) | |
CuFe2O4@ g-C3N4 | self-assembly method | 500 W Xe lamp | 0.1 g/L | 0.01 M | OII 98% (3.5 h) |