(59ag) N-Doped Cu/Cuxo/C Foam Catalyst Having Multi-Crystaline Derived from Alkaline N-Coordinated HKUST-1/CMC for Enhanced 4-Nitrophenol Reduction
AIChE Spring Meeting and Global Congress on Process Safety
2019
2019 Spring Meeting and 15th Global Congress on Process Safety
Spring Meeting Poster Session and Networking Reception
Spring Meeting Poster Session
Monday, April 1, 2019 - 5:00pm to 7:00pm
N-doped Cu/CuxO/C foam catalysts with multi-crystalline are synthesized from N-coordinated HKUST-1/cellulose for enhanced 4-nitrophenol reduction. Effect of N content and basicity on Cu morphology, crystal lattice and size, component dispersion and oxidation states in catalysts are systematically investigated. The facility of nano-catalyst synthesis from crystalline powders to robust morphology based foamed catalysts strategy is confirmed crediting to its simplicity and industrial applications. It is revealed that (1) graphitic nano-structure has been detected from carbonized N-doped HKUST-1 due to the catalysis of Cu sites towards C/N elements in HKUST-1; (2) alkaline N-doping inhibits the crystal growth of Cu species, resulting in crystal size of 3-5 nm in porous catalyst samples; (3) DFT simulation verifies that N doping will lower HOMO and LUMO energies of Cu-BTC in various degree It significantly restrains a complete reduction of Cu ions in HKUST-1, and facilitates the formation of a multi-crystalline Cu/CuxO/C based from HKUST-1 calcination; (4) amount of Cu2O in N-doped Cu/CuxO/C gradually increases with the enhanced alkaline strength and content of the N dopant in HKUST-1. Catalysis performance exhibits that our designed N-doped Cu/CuxO/C based from HKUST-1s show much higher fast catalysis kinetics and better recycle performance on par with the start-of-the-art catalysts. Among which, melamine-doped Cu/CuxO/C foam catalyst exhibits the most outstanding activity in the reduction of 4-nitrophenol with a kinetic rate of 1.75 min-1, 21 times faster comparing with bare Cu/C catalyst based on pristine HKUST-1, demonstrating the critical contribution of the foamed morphology and multi-crystalline of Cu/CuxO/C to the outstanding activity and recycle performance.