The reduction of CO(2)into C(1)feedstocks (e.g., CO) by utilizing solar energy has attracted increasing attention for the efficient production of renewable energy. However, a significant challenge in the reduction of CO(2)is achieving high conversion efficiency due to the high C=O dissociation energy of CO(2)and difficultly in accessing the surface of photocatalysts. Herein, we fabricated a polymeric carbon nitride (PCN) catalyst with hydroxyethyl groups grafted on its edgeviaa facile bottom-up strategy, facilitating the efficient surface absorption of CO(2)and lowering the CO(2)transformation energy barrier; this was accompanied with exceptional extended optical absorption ability to the near-infrared region and increase in the density of states at the Fermi level. Thus, concentrated CO(2)molecules could contact the surface of PCN and be easily activated; this resulted in an excellent CO production rate of up to 209.24 mu mol h(-1)g(-1)in the modified PCN (i.e., 39.5-fold increase compared to that of pristine PCN) and a selectivity of 98.5% under white LED illumination, exceeding that of most PCN-based energy conversion systems reported to date. Notably, this PCN matrix also exhibited photocatalytic activity for the production of CO in the near-infrared region from 780 to 850 nm. These results pave the way for the development of structured photocatalysts with easy accessibility for CO(2)and broadband spectral response for the efficient photocatalytic reduction of CO2.

• 单位
  TEST; 浙江大学; test