Photocatalysis based on semiconductors has attracted particular interest in the past four decades because of its ability to directly convert solar energy into chemical fuels. In recent years, much effort has been devoted to investigating the photocatalytic properties of potassium niobate oxides, K4Nb6O17, K2Nb2O6, and KNbO3, due to their unique crystal and energy band structures. In particular, K4Nb6O17 with a layered anisotropic structure has high potential for photocatalytic applications. However, K4Nb6O17, like other UV light responsive semiconductor photocatalysts, cannot exhibit any photocatalytic activity under visible light irradiation, due to its relatively large bandgap (3.2 eV). Thus, it is highly desirable to develop an effective method to reduce the bandgap of K4Nb6O17 for capturing more solar energy. Among various methods for reducing the bandgap of K4Nb6O17, doping is the most commonly used method because it can induce intrinsic electronic and band structure changes.
Although doping of metal ions into the lattice of K4Nb6O17 can extend its visible light response, the introduction of dopants can also result in thermal or crystal instability and increased charge carrier recombination centers, and thus low photocatalytic efficiency. Recently, it has been demonstrated that self-doping, different from conventional impurity incorporation, is an effective and promising way to extend the visible light absorption of semiconductor photocatalysts. By introducing Ti3+ or oxygen vacancies, both anatase and rutile TiO2 have shown enhanced visible-light-driven photocatalytic activities. Hu and coworkers found that Ta4+ self-doped in bulk NaTaO3 can remarkably narrow its bandgap from 3.94 to 1.70 eV, and thus extend its photoresponse from the UV to the visible light region, leading to enhanced visible-light-driven photocatalytic activity. Nonetheless, to the best of our knowledge, there is no report on Nb4+ self-doped niobates with high solar absorption and improved photocatalytic H2 production activity yet.
Black Nb4+ self-doped K4Nb6O17 microspheres were prepared for the first time through a facile UV light photoreduction method. By the introduction of Nb4+, the defective K4Nb6O17 can harvest the full spectrum of visible light as well as near-infrared light. The black K4Nb6O17 microspheres showed improved visible-light-driven photocatalytic H2 production activity. Importantly, the present synthetic approach is also applicable to the preparation of other Nb4+ self-doped niobates.
Chem. Commun.,2014
(A) Photographs of K4Nb6O17 in aqueous methanol solution before (left) and after (right) UV light irradiation. (B) UV-vis diffuse reflectance spectra of the white and black Nb4+ self-doped K4Nb6O17 samples.
(A) XRD patterns of the white K4Nb6O17 and black Nb4+ self-doped K4Nb6O17 samples. (B) TEM image of the black Nb4+ self-doped K4Nb6O17 sample.
