Surface structure tuning of BiOCl nanosheets by the sequential introduction of oxygen vacancies, PO₄^3- and Ag⁺ for boosting photodegradation of tetracycline hydrochloride

The surface structure significantly impacts the physicochemical properties of semiconductors. Constructing heterojunction is a universal approach to tune surface structure, which can effectively accelerate the charge transfer at the interface. Here, BiOCl nanosheets which occupy high ratio of surface atoms to entire atoms were used as a model photocatalyst, and a strategy was proposed to tune its surface structure by sequential introduction of oxygen vacancies, PO₄^3- and Ag⁺ on surface of BiOCl nanosheets. In order to inhibit the overgrowth of heterogeneous component, the excess PO₄^3- was timely removed by centrifugation before adding Ag⁺. As a result, the as-obtained optimal sample which was confirmed to be a composite composed of BiOCl, BiPO₄ and AgCl showed superior photocatalytic activity for tetracycline hydrochloride degradation with the rate of 38 times higher than that of pristine BiOCl, which was mainly attributed to the quick migration of photongenerated carrier. The active species h⁺ and •O₂^- played a vital role in this degradation process. Our strategy not only greatly saved investment of noble metal Ag, but also provide superior stability. On the basis of experimental results and density functional theory calculation, the visible-light driven catalytic mechanism was revealed.