Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
6453409 | Applied Catalysis B: Environmental | 2018 | 8 Pages |
CdS is a photocatalyst known for its desirable bandgap and availability but it is limited by photocorrosion and inefficiency issues in practical applications. According to band engineering theory, regulating the width of bonding region that exists between cubic phase and hexagonal phase, we design a suitable phase junction and achieve effective separation of electron-hole pairs. Thus, the problems caused by photocorrosion and phase exclusion can be resolved. The optimal photocatalytic activity of the prepared material is 4.9 mmol hâ1 gâ1 with 41.5% quantum efficiency at the wavelength of 420 nm, which is 60 times higher than that of the initial samples (cubic or hexagonal phase), and keeps high photocatalytic stability. This novel construction approach can be useful in designing ideal band structures and matching the phase bandgap of other binary sulfides.
Graphical abstractDownload high-res image (220KB)Download full-size imageHighlightsâ¢Suitable band engineering is important in separating photo-generated electron-hole pairs.â¢We designed a novel CdS nano-photocatalyst with bonding-region-width-controlled phase junction.â¢This CdS nano-photocatalyst shows high-efficiency photocatalytic activity (4.9 mmol·hâ1·gâ1) and high-stability.