Artificial solid Z-scheme system, imitating the natural photosynthesis system, has attracted much interest due to its property of maintaining holes and electrons at high redox potential. Recently, metal tungstate (MWO₄) has caused much attention because of its appropriate bandgap and interesting physicochemical properties. High efficiency solid Z-scheme system CdWO₄/CdS has been reported. However, the bandgap of CdWO₄ (3.64 eV) is too large for visible light absorption. Other MWO₄ have suitable bandgaps (indirect bandgap: NiWO₄, 1.82 eV; CoWO₄, 1.80 eV; ZnWO₄, 3.14 eV), but their photocatalytic applications are not yet explored. Therefore, the purpose here is to utilize MWO₄ as PS2 to fabricate novel solid Z-scheme systems for photocatalytic H₂ generation.

MWO₄/Pt/CdS (M=Co, Ni, Zn) were fabricated in 3 steps. MWO₄ were synthesized by reaction between M(NO₃)₂ and Na₂WO₄. Then platinum was modified on MWO₄ through the reduction of H₂PtCl₆ by NaBH₄. Finally, CdS was synthesized on MWO₄/Pt through the reaction between Cd(CH₃COO)₂ and CH₃CSNH₂ in MWO₄/Pt aqueous suspension. During this step in synthesis of NiWO₄/Pt/CdS, CH₃CSNH₂ were 0.014, 0.042, 0.07 g and the samples were labelled as NWCS1, NWCS2, NWCS3 respectively. Photocatalytic reactions were taken in lactic acid solution under 550 W Xenon lamp.

Photocatalytic H₂ generation of NiWO₄/Pt/CdS, CoWO₄/Pt/CdS, ZnWO₄/Pt/CdS were 17.5, 15.8, and 4.4 mL/2 h respectively. As bandgap of ZnWO₄ is much larger than those of NiWO₄ and CoWO₄, the low performance of ZnWO₄/Pt/CdS may be induced by the low charge separation rate of ZnWO₄ under visible light. Ratio of S increased and W decreased with the increase of CH₃CSNH₂ concentration from NWCS1 to NWCS3. The result indicated that S^2–concentration has an effect on the elemental composition of the photocatalysts obtained.

Another results will be presented in our session.