Loading Nickel Atoms on GDY for Efficient CO2 Fixation and Conversion

Carbon dioxide(CO2) is an important and valuable C1 resource for the synthesis of numerous of value-added products. However, efficient fixation and conversion of CO2 into organic carbonates under mild conditions remain great challenges. Herein, graphdiyne(GDY)-based nickel atomic catalysts(Ni-0/GDYs) were synthesized through a facile in-situ reduction method. Experimental results showed that the obtained Ni-0/GDY had outstanding catalytic performances for converting CO2 into cyclic carbonates with a high reaction conversion(99%) and reaction selectivity(ca. 100%) at 80 degrees C and under 1 atm(1 atm=101325 Pa). Specially, the activation energy (E-a) value for the Ni-0/GDY is 37.05 kJ/mol, lower than those of reported catalysts. The reaction mechanism was next carefully analyzed by using density functional theory(DFT) calculations. Such an excellent catalytic property could be mainly attributed to the high dispersion of active sites on the Ni-0/GDY, and the unique incomplete charge transfer properties of GDY-based zero-valent metallic catalysts.

Automated summary

Graphdiyne-based nickel atomic catalysts (Ni-0/GDY) demonstrate outstanding catalytic performance for converting CO2 into cyclic carbonates under mild conditions, with high reaction conversion and selectivity. The low activation energy, high dispersion of active sites, and unique incomplete charge transfer properties contribute to the excellent catalytic property of Ni-0/GDY.