Mesoporous Mixed-Metal–Organic Framework Incorporating a [Ru(Phen)<sub>3</sub>]<sup>2+</sup> Photosensitizer for Highly Efficient Aerobic Photocatalytic Oxidative Coupling of Amines
Dongjie Bai, Jinlin Qiu, Jingzhe Li, Shengbin Zhou, Xiang Cui, Xiaoliang Tang, Yu Tang, Weisheng Liu, Banglin Chen
Abstract
[Ru(Phen) 3 ] 2+ (phen = phenanthroline) as a very classical photosensitizer possesses strong absorption in the visible range and facilitates photoinduced electron transfer, which plays a vital role in regulating photochemical reactions. However, it remains a significant challenge to utilize more adequately and exploit more efficiently the ruthenium-based materials due to the uniqueness, scarcity, and nonrenewal of the noble metal. Here, we integrate the intrinsic advantages of the ruthenium-based photosensitizer and mesoporous metal–organic frameworks (meso-MOFs) into a [Ru(Phen) 3 ] 2+ photosensitizer-embedded heterometallic Ni(II)/Ru(II) meso-MOF ( LTG-NiRu ) via the metalloligand approach. LTG-NiRu, with an extremely robust framework and a large one-dimensional (1D) channel, not only makes ruthenium photosensitizer units anchored in the inner wall of meso-MOF tubes to circumvent the problem of product/catalyst separation and recycling of catalysts in heterogeneous systems but also exhibits exceptional activities for the aerobic photocatalytic oxidative coupling of amine derivatives as a general photocatalyst. The conversion of the light-induced oxidative coupling reaction for various benzylamines is ∼100% in 1 h, and more than 20 chemical products generated by photocatalytic oxidative cycloaddition of N-substituted maleimides and N, N -dimethylaniline can be synthesized easily in the presence of LTG-NiRu upon visible light irradiation. Moreover, recycling experiments demonstrate that LTG-NiRu is an excellent heterogeneous photocatalyst with high stability and excellent reusability. LTG-NiRu represents a great potential photosensitizer-based meso-MOF platform with an efficient aerobic photocatalytic oxidation function that is convenient for gram-scale synthesis.