Stable O<sub>3</sub> Decomposition by Layered Double Hydroxides: The Pivotal Role of NiOOH Transformation
Jiaqi Li, Yixing Ma, Fengyu Li, Ziruo Zeng, Hengxi Zhu, Chunxue Wang, Langlang Wang, Kai Li, Xueqian Wang, Ping Ning, Fei Wang
Abstract
Because ozone (O 3 ) is a significant air pollutant, advanced O 3 elimination technologies, particularly those under high-humidity conditions, have become an essential research focus. In this study, a nickel–iron layered double hydroxide (NiFe-LDH) was modified via intercalation with octanoate to develop an effective hydrophobic catalyst (NiFe-OAa-LDH) for O 3 decomposition. The NiFe-OAa-LDH catalyst sustained its O 3 decomposition rate of >98% for 48 h under conditions of 90% relative humidity, 840 L/(g·h) space velocity, and 100 ppm inlet O 3 concentration. Moreover, it maintained a decomposition rate of 90% even when tested at a higher airflow rate of 2500 L/(g·h). Based on the changes induced by the Ni–O II to Ni–O III bonds in NiFe-OAa-LDH during O 3 treatment, catalytic O 3 decomposition was proposed to occur in two stages. The first stage involved the reaction between the hydroxyl groups and O 3, leading to the breakage of the O–H bonds, formation of NiOOH, and structural changes in the catalyst. This transformation resulted in the formation of abundant and stable hydrogen vacancies. According to density functional theory calculations, O 3 can be effectively decomposed at the hydrogen vacancies with a low energy barrier during the second stage. This study provides new insights into O 3 decomposition.