Defect engineering in MIL-125-(Ti)-NH2 for enhanced photocatalytic H2 generation

Pre-designing starting materials is a sensible approach to tailor the synthetic, optoelectronic, and physicochemical properties of a photocatalyst towards higher activity without the need for additional active species. MIL-125-(Ti)-NH2, a metal-organic framework (MOF) photocatalytically active for H-2 evolution, was first successfully synthesised at a relatively low temperature of 70 degrees upon employing pre-designed titanium-oxo-carboxylate clusters. While rearrangement of the original cluster enabled successful MIL-125-(Ti)-NH2 formation, its ligand stoichiometry favoured MOFs with abundant defects at the Ti centres which in turn acted as accessible active sites for H-2 generation. The catalytic sites and their local geometry were studied by pyridine-adsorbed Fourier transform infrared spectroscopy, X-ray absorption near-edge structure, and extended X-ray absorption fine structure. Interestingly, the frameworks prepared using pre-designed titanium-oxo clusters can alter electronic optical properties and energy levels. In the presence of triethanolamine as an electron donor and under visible light irradiation, this led to a similar to 3.5 times higher H-2 evolution rate in the titanium-oxo cluster MOF compared to MIL-125-(Ti)-NH2 obtained by typical hydrothermal synthesis. The obtained catalyst also exhibits a good-reusable performance for at least three consecutive runs without any loss in its reactivity. Pre-designed clusters can be simply utilised to generate accessible active sites and manipulate electrical properties for enhancing catalytic performance.

Automated summary

Pre-designing starting materials is an effective strategy to enhance the activity of a photocatalyst without the need for additional active species. In this study, pre-designed titanium-oxo-carboxylate clusters were used to synthesize a metal-organic framework (MOF) photocatalyst MIL-125-(Ti)-NH2 for H-2 evolution. The resulting MOFs possessed abundant defects at the Ti centers, which acted as accessible active sites for H-2 generation. The use of pre-designed clusters also altered the electronic optical properties and energy levels, leading to a significantly higher H-2 evolution rate compared to the traditional hydrothermal synthesis method.