3D-printing advanced ZIF-67@aluminum phosphate/Al2O3 ceramic catalyst by aluminum phosphate-assisted surface bonding
Yuxiong Guo, Shengcai Wu, Peiqing La, Dekai Zhou, Zhongying Ji, Xiaolong Wang
Abstract
The 3D-printed ceramic catalyst has a broad range of application prospects. Notably, the ZIF-67-loaded 3D-printed ceramic catalyst demonstrates exceptional catalytic performance and a high degree of structural design flexibility. However, the ceramics prepared by the direct loading of ZIF-67 onto ceramic substrates during 3D printing show insufficient catalytic stability. In this study, aluminum phosphate (AP) was used as a binder to enhance the adhesion between ZIF-67 and the Al2O3 ceramic support surface, thereby reducing ZIF-67 shedding and preventing the degradation of the catalytic performance of the 3D-printed ceramic catalyst. Consequently, after six cycles, the conversion rate of 4-nitrophenol with ZIF-67/Al2O3 decreased by 31%, whereas that with ZIF-67@AP/Al2O3 decreased by only 5.4%. The reasons for the high catalytic stability of ZIF-67@AP/Al2O3 were comprehensively and meticulously investigated. The proposed synthesis strategy, which utilizes AP to facilitate the bonding of ZIF-67 to the Al2O3 ceramic scaffold, offers a novel approach for enhancing the catalytic stability of 3D-printed ceramic catalysts loaded with active species through self-growth methods. This approach is expected to guide future research on efficient catalytic systems for various applications.