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Phase transition induced hydrogen activation for enhanced furfural reductive amination over a CoCu bimetallic catalyst. | LitMetric

AI Article Synopsis

  • - The synthesis of primary amines from renewable biomass through reductive amination is gaining popularity, but creating effective non-noble-metal catalysts for low-temperature processes remains a challenge.
  • - Researchers have developed a new Cu-doped Co@CoO catalyst that shows 1.57-45 times greater efficiency in catalyzing room temperature reactions compared to earlier Co@CoO designs, surpassing even some noble metal catalysts.
  • - The study reveals that Cu doping changes the cobalt structure and enhances electron transfer, creating dual active sites that boost hydrogen activation and dissociation, leading to improved performance in the reductive amination of furfural (FAL).

Article Abstract

The synthesis of primary amines from renewable biomass and its derivatives through reductive amination has garnered significant attention. How to construct efficient non-noble-metal catalysts that enable low-temperature catalysis still remains challenging. Herein, we report a Cu-doped Co@CoO heterostructure catalyst that features structural Co-CoCuO bifunctional sites, which enable room temperature reductive amination of various aldehydes with 1.57-45 times higher efficiency than Co@CoO , outperforming many reported non-noble and even noble metal catalysts. Experiments and DFT calculations indicate that Cu doping leads to a phase transition of Co from hcp to fcc, while electrons are transferred from Cu to Co, forming a dual active site with electron-rich Co closely interacting with CoCuO . These electron-rich Co sites demonstrate excellent activity in the activation and dissociation of hydrogen, while the CuO component facilitates hydrogen spillover at the CoCuO interface, thus resulting in a highly efficient cooperative effect for the furfural (FAL) reductive amination. This work provides general guidance for the rational design of high-performance reductive amination catalysts for biomass upgrading.

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Source
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11577266PMC
http://dx.doi.org/10.1039/d4sc05885bDOI Listing

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