One-step chemical bath co-precipitation method to prepare high hydrogen-producing active ZnxCd1-xS solid solution with adjustable band structure

A series of ZnxCd1-xS solid solutions were synthesized through a simple one-step chemical bath co-precipitation route. The microstructure, morphology, composition and optical properties had been thoroughly investigated. The results showed that the as-obtained ZnxCd1-xS samples exhibited monodisperse spherical feature. These monodisperse ZnxCd1-xS spheres were composed of a large number of 5-10 nm crystal grains. The chemical composition of the ZnxCd1-xS solid solutions can be controlled by adjusting the ratio of Zn source to Cd source and the dosage of ammonia solution. Meanwhile, the energy band structure and photocatalytic properties can be optimized. The photocatalysis experiment results revealed that the as-synthesized Zn0.30Cd0.70S sample exhibited optimum water splitting performance. The satisfactory hydrogen evolution rate (HER) of Zn0.30Cd0.70S reached 27.004 mmol g(-1) h(-1) even without any cocatalysts, which was more than 48 times that of pure CdS (0.561 mmol g(-1) h(-1)). This enhancing effect can owe to the balance between light absorption capacity and redox potential caused by the incorporation of Zn in the ZnxCd1-xS solid solutions.

Automated summary

A series of ZnxCd1-xS solid solutions were synthesized via a one-step chemical bath co-precipitation method. The chemical composition of these solid solutions can be controlled by adjusting the ratio of Zn source to Cd source and the dosage of ammonia solution. In photocatalysis experiments, the Zn0.30Cd0.70S sample showed optimum water splitting performance with a high hydrogen evolution rate.