Abstract

The development of highly active perovskite-based catalysts for the oxidation of volatile organic chemicals (VOCs) has drawn a great deal of attention. A-site defect regulation is found to be effective to improve the catalytic performance, but the relationship between structure variation and catalytic activity has not been clearly unveiled. Herein, this issue was interpreted by the variation of physicochemical properties and electronic structure (O p-band center). An in situ one-step calcination method with NH4HCO3 addition was adopted to prepare a series of A-site-deficient LaCoO3 perovskites (LxCO), which were characterized by XRD, TEM, EELS, ESR, XPS, UPS, H2-TPR, and O2-TPD and catalytic test toward toluene oxidation. The catalytic activity displayed a volcano-type relationship with an addition amount of NH4HCO3. The electronic structure determined the reducibility and active oxygen content and accordingly affected the catalytic activity of LxCO. The obtained results provide theoretical and technical support for the design of efficient VOC oxidation catalysts.