Black magnetic Cu-g-C3N4 nanosheets towards efficient photocatalytic H2 generation and CO2/benzene conversion

Copper (Cu) clusters are incorporated into graphitic carbon nitride (g-C3N4) via a two-step thermal polymerization process, forming a superior thin black g-C3N4 nanosheets based Cu cluster composite (Cu-g-C3N4) with highly efficient charge transfer characteristic and enhanced photocatalytic activity. The Cu-N bonding is formed through intercalation of copper atoms (using Cu (II) acetylacetonate as Cu source) into dicyandiamide-based supramolecular precursor via mechano-chemical reaction, and the Cu atoms and the N atoms are bonded together in two ways: between one Cu atom and four coordinated N atoms (that comes from adjacent carbon nitride layers) and between one central Cu atom and the three N atoms from identical carbon nitride layer forming an in-plane system. Enhanced ferromagnetism of black Cu-g-C3N4 nanosheets is found for the first time, opening the way to deepen the understanding of the material in novel undiscovered applications and to generate fundamental knowledge of ferromagnetism of Cu incorporated g-C3N4 composite material. This black Cu-g-C3N4 nanosheets composite reveals enhanced visible-light-responsive photocatalytic hydrogen generation (526 mu mol g(-1) h(-1)) as well as excellent CO (5.0 mu mol g(-1)h(-1)) and CH4 generation (2.4 mu mol g(-1)h(-1)) efficiency. Moreover, outstanding conversion rate (90.4 %) and high selectivity to phenol (99.1 %) are obtained in visible-light-driven benzene oxidation application.

Automated summary

Copper clusters are incorporated into graphitic carbon nitride via a two-step thermal polymerization process, forming a superior Cu-g-C3N4 composite with highly efficient charge transfer and enhanced photocatalytic activity. The black Cu-g-C3N4 nanosheets exhibit enhanced ferromagnetism, providing fundamental knowledge of Cu-incorporated g-C3N4 composite material. This composite also shows excellent visible-light-responsive photocatalytic hydrogen generation and benzene oxidation performance.