The influence of rc-Ce2Zr2O8 content on three-way catalytic performance

The CeO2-ZrO2 based oxide (CZ) with rcappa-phase CZ (rc-Ce2Zr2O8) has been examined as a promising alternative to the traditional CZ used in the three-way catalysts (TWCs). However, forming pure rc-Ce2Zr2O8 requires huge energy, and it remains obscure whether more rc-Ce2Zr2O8 is better. Herein we synthesized a series of CZ with increasing rc-Ce2Zr2O8 content by increasing reduction time, as well as the supported Pd-only catalysts, for investigating the influence of rc-Ce2Zr2O8 content on TWC performance. The results evidenced that rc-Ce2Zr2O8 started to form at surface and gradually covered the whole surface. The crystal interface between rc-Ce2Zr2O8 and the cubic-phase matrix, was thus first increased but then decreased as the rc-Ce2Zr2O8 content increased from 0 % to 34.3 %. Interestingly, the presence of 19.8 % rc-Ce2Zr2O8 could dramatically improve the reducibility of CZ, making reduction temperature decrease from 598 & DEG;C to 446 & DEG;C, however, further improvement was not achieved by increasing rc-Ce2Zr2O8. More importantly, the Pd-CZ interaction strength was found to be positively corelated with the amount of the mentioned crystal interface. The catalytic activity followed the similar variation tendency with the Pd-CZ interaction. Among them, Pd/CZ1 with 19.8 % rc-Ce2Zr2O8 showed the optimal catalytic performance. Based on the analyses, the improved TWC performance by rc-Ce2Zr2O8 was ascribed to the strengthened Pd-CZ interaction. Therefore, instead of increasing the rc-Ce2Zr2O8 content by consuming huge energy, constructing larger content of the mentioned crystal interface is more efficient for improving TWC performance.

Automated summary

In this study, CZ with increasing rc-Ce2Zr2O8 content was synthesized by increasing reduction time, and the influence of rc-Ce2Zr2O8 content on TWC performance was investigated. It was found that 19.8% rc-Ce2Zr2O8 could significantly improve the reducibility of CZ and enhance the catalytic activity of TWCs. Therefore, constructing a larger crystal interface between rc-Ce2Zr2O8 and the cubic-phase matrix is more efficient than increasing the rc-Ce2Zr2O8 content by consuming huge energy for improving TWC performance.