Abstract
No visible light activity is the bottle neck for wide application of TiO(2), and Boron doping is one of the effective way to broaden the adsorption edge of TiO(2). In this study, several Boron doped TiO(2) materials were prepared via a facile co-precipitation and calcination process. The B doping amounts were optimized by the degradation of rhodamine B (Rh B) under visible light irradiation, which indicated that when the mass fraction of boron is 6% (denoted as 6B-TiO(2)), the boron doped TiO(2) materials exhibited the highest activity. In order to investigate the enhanced mechanism, the difference between B-doped TiO(2) and bare TiO(2) including visible light harvesting abilities, separation efficiencies of photo-generated electron-hole pairs, photo-induced electrons generation abilities, photo-induced charges transferring speed were studied and compared in details. h(+) and (·) O2- were determined to be the two main responsible active species in the photocatalytic oxidation process. Besides the high degradation efficiency, 6B-TiO(2) also exhibited high reusability in the photocatalysis, which could be reused at least 5 cycles with almost no active reduction. The results indicate that 6B-TiO(2) has high photocatalytic degradation ability toward organic dye of rhodamine B under visible light irradiation, which is a highly potential photocatalyst to cope with organic pollution.