Catalytic-CO(2)-Desorption Studies of BZA-AEP Mixed Absorbent by the Lewis Acid Catalyst CeO(2)-γ-Al(2)O(3)

Traditional organic amines exhibit inferior desorption performance and high regeneration energy consumption. The implementation of solid acid catalysts presents an efficacious approach to mitigate regeneration energy consumption. Thus, investigating high-performance solid acid catalysts holds paramount importance for the advancement and implementation of carbon capture technology. This study synthesized two Lewis acid catalysts via an ultrasonic-assisted precipitation method. A comparative analysis of the catalytic desorption properties was conducted, encompassing these two Lewis acid catalysts and three precursor catalysts. The results demonstrated that the CeO(2)-γ-Al(2)O(3) catalyst demonstrated superior catalytic desorption performance. Within the desorption temperature range of 90 to 110 °C, the average desorption rate of BZA-AEP catalyzed by the CeO(2)-γ-Al(2)O(3) catalyst was 87 to 354% greater compared to the desorption rate in the absence of the catalyst, and the desorption temperature can be reduced by approximately 10 °C. A comprehensive analysis of the catalytic desorption mechanism of the CeO(2)-γ-Al(2)O(3) catalyst was conducted, and indicated that the synergistic effect of CeO(2)-γ-Al(2)O(3) conferred a potent catalytic influence throughout the entire desorption process, spanning from the rich solution to the lean solution.