Hydrophobic Porphyrin Titanium-Based MOFs for Visible-Light-Driven CO<sub>2</sub> Reduction to Formate
Zhi Jin, Dandan Liu, Xin Liu, Xin Liu, Peng Chen, Dashu Chen, Hongzhu Xing, Xianchun Liu, Xianchun Liu
Abstract
Three hydrophobic porphyrin titanium-based metal–organic frameworks (MOFs) (HPA/DGIST-1, DPA/DGIST-1, and OPA/DGIST-1) were synthesized through a postsynthetic coordination reaction by using alkylphosphonic acid of different lengths (HPA, hexylphosphonic acid; DPA, dodecylphosphonic acid; OPA, octadecylphosphonic acid). Compared with the hydrophilic DGIST-1, modified DGIST-1 exhibits excellent hydrophobicity and presents good stability in humid atmospheres. Due to the introduction of porphyrin ligands, HPA/DGIST-1, DPA/DGIST-1, and OPA/DGIST-1 showed good visible-light absorption (380–700 nm) and sensitive photogenerated charge responses. When acted as catalysts, these hydrophobic Ti-MOFs can selectively reduce CO 2 to HCOO – under visible-light irradiation with average reaction rates of 150.9, 178.5, and 228.3 μmol·h –1 ·g –1, where these values are 1.3–2.0 times higher than the system mediated by the initial porphyrin Ti-MOF catalyst. 13 C NMR spectroscopy demonstrates that the catalytic product HCOO – anion originates from the reactant CO 2 . The photocatalytic experiments, electron paramagnetic resonance, and photoluminescence spectra tests showed that porphyrin ligands and Ti–O units can act as catalytic activity centers to realize the conversion of CO 2 to HCOO – . This work demonstrated that the combination of porphyrin titanium-based MOF and alkyl hydrophobic groups is an effective way to enhance the stability of titanium-based MOFs and maintain their high photocatalytic performance.