Ag/AgBr/TiO₂

420 nm

E. coli

2.76E−01

350 W Xenon lamp with λ > 420 nm made by cut-off filter

[96]

Photocatalyst synthesized by deposition-precipitation method

0.2 g/l of photocatalyst used

Ag-Bi₂WO₆

420 nm

E. coli

0.1535

500 W xenon lamp with λ > 420 nm made by cut-off filter

[87]

S. epidermidis

0.06108

0.5 mg/ml of photocatalyst used

Photocatalyst synthesized by facile alcohol-thermal process

AgBr/TiO₂

420 nm

E. coli

0.2609

Photocatalyst synthesized by deposition-precipitation method

[90]

S. aureus

0.3914

350 W xenon lamp with λ > 420 nm made by cut-off filter

0.2 g/l of photocatalyst used

Ag₃PO₄/TiO₂

400 nm

E. coli

0.1314

Photocatalyst synthesized by direct precipitation method

[88]

300 W xenon lamp with λ > 400 nm made by cut-off filter

10 mg/L of photocatalyst used

AgI/TiO₂

420 nm

E. coli

2.99E−01

350 W xenon lamp with λ > 420 nm made by cut-off filter

[97]

S. aureus

0.1612

Photocatalyst synthesized by deposition-precipitation method

0.2 g/l of photocatalyst used

Ag₃PO₄/TiO₂/Fe₃O₄

420 nm

E. coli

1.243

300 W xenon lamp with λ > 420 nm made by cut-off filter

[98]

Photocatalyst synthesized by in-situ hydrolysis, deposition-precipitation method

0.30 mg photocatalyst was used in an anti-microbial film

Ag/g-C3N₄

420 nm

E. coli

1.84E−01

300 W xenon lamp with λ > 420 nm made by cut-off filter

[99]

Complex synthesis procedure

0.1 g/l photocatalyst used

Ag/AgBr/WO₃·3H₂O

400 nm

E. coli

0.0693

300 W xenon lamp with λ > 400 nm made by cut-off filter

[100]

Photocatalyst synthesized by Ion-Exchange method

0.1 g/l of photocatalyst used

Ag/AgBr/BiOBr

400 nm

E. coli

0.4621

Photocatalyst synthesized by solvothermal-ion exchange method

[101]

300 W xenon lamp with λ > 400 nm made by cut-off filter