Fructose-regulated ZnO single-crystal nanosheets with oxygen vacancies for photodegradation of high concentration pollutants and photocatalytic hydrogen evolution

Abstract

ZnO-based photocatalysts have been widely applied to photocatalytic reactions. However, the pure phase ZnO is rarely used in degradation of refractory pollutants and photocatalytic hydrogen evolution due to its poor photo-redox ability. In this study, we develop a novel surface atom regulation strategy using fructose molecules containing hydroxyl groups to improve photo-oxidation ability of ZnO. Interestingly, the fructose-regulated ZnO nanosheets with oxygen vacancies exhibit more positive surface valence band maximum than that of pristine ZnO. The photogenerated holes with strong oxidation capacity can be formed on the fructose-regulated ZnO nanosheets. The fructose-regulated ZnO nanosheets can rapidly degrade high concentration of phenol and other organic pollutants, which is difficultly achieved by the pristine ZnO nanosheets. In addition, photocatalytic H2 production activity is also found on our pure phase ZnO. This work provides a new design strategy for modifying the surface structure of photocatalysts to improve photocatalytic performance.