Abstract
Perfluorinated compounds (PFCs) are emerging environmental pollutants characterized by their extreme stability and resistance to degradation. Among them, tetrafluoromethane (CF(4)) is the simplest and most abundant PFC in the atmosphere. However, the highest C─F bond energy and its highly symmetrical structure make it particularly challenging to decompose. In this work, a yolk-shell Al(2)O(3) micro-reactor is developed to enhance the catalytic hydrolysis performance of CF(4) by creating a local autothermic environment. Finite element simulations predict that the yolk-shell Al(2)O(3) micro-reactor captures the heat released during the catalytic hydrolysis of CF(4), resulting in a local autothermic environment within the yolk-shell structure that is 50 °C higher than the set temperature. The effectiveness of this local autothermic environment is experimentally confirmed by in situ Raman spectroscopy. As a result, the obtained yolk-shell Al(2)O(3) micro-reactor achieves 100% CF(4) conversion at a considerably low temperature of 580 °C for over 150 h, while hollow and solid Al(2)O(3) structures required higher temperatures of 610 and 630 °C, respectively, to achieve the same conversion rate, demonstrating the potential of yolk-shell Al(2)O(3) micro-reactor to significantly reduce the energy requirements for PFCs degradation and contribute to more sustainable and effective environmental remediation strategies.