Formaldehyde Ambient-Temperature Decomposition over Pd/Mn 3 O 4 -MnO Driven by Active Sites' Self-Tandem Catalysis.
Xiao-He LiuTong LuXinguo JiaoZeyu JiangChangwei ChenYadi WangYanfei JianChi HePublished in: Environmental science & technology (2024)
The widespread presence of formaldehyde (HCHO) pollutant has aroused significant environmental and health concerns. The catalytic oxidation of HCHO into CO 2 and H 2 O at ambient temperature is regarded as one of the most efficacious and environmentally friendly approaches; to achieve this, however, accelerating the intermediate formate species formation and decomposition remains an ongoing obstacle. Herein, a unique tandem catalytic system with outstanding performance in low-temperature HCHO oxidation is proposed on well-structured Pd/Mn 3 O 4 -MnO catalysts possessing bifunctional catalytic centers. Notably, the optimized tandem catalyst achieves complete oxidation of 100 ppm of HCHO at just 18 °C, much better than the Pd/Mn 3 O 4 (30%) and Pd/MnO (27%) counterparts as well as other physical tandem catalysts. The operando analyses and physical tandem investigations reveal that HCHO is primarily activated to gaseous HCOOH on the surface of Pd/Mn 3 O 4 and subsequently converted to H 2 CO 3 on the Pd/MnO component for deep decomposition. Theoretical studies disclose that Pd/Mn 3 O 4 exhibits a favorable reaction energy barrier for the HCHO → HCOOH step compared to Pd/MnO; while conversely, the HCOOH → H 2 CO 3 step is more facilely accomplished over Pd/MnO. Furthermore, the nanoscale intimacy between two components enhances the mobility of lattice oxygen, thereby facilitating interfacial reconstruction and promoting interaction between active sites of Pd/Mn 3 O 4 and Pd/MnO in local vicinity, which further benefits sustained HCHO tandem catalytic oxidation. The tandem catalysis demonstrated in this work provides a generalizable platform for the future design of well-defined functional catalysts for oxidation reactions.
Keyphrases
- room temperature
- metal organic framework
- transition metal
- physical activity
- mental health
- highly efficient
- air pollution
- hydrogen peroxide
- public health
- nitric oxide
- particulate matter
- mass spectrometry
- dna methylation
- gene expression
- genome wide
- electron transfer
- molecular dynamics simulations
- single cell
- high speed
- single molecule