Meng-Lu Lin scite author profile

Here, we report our trials to regulate the luminescence performance of the macrocyclic samarium(III) complex and prepare four excellent luminescent Sm(III) complex-doped poly(methylmethacrylate) (PMMA) composites. Four 23-membered [1 + 1] Schiff-base macrocyclic mononuclear Sm(III) complexes, Sm-2a–Sm-2d, originating from dialdehydes with different pendant arms and 1,2-bis(2-aminoethoxy)ethane, have been constructed by the template method. Crystal structures reveal that every Sm(III) ion with the coordination geometry of a distorted bicapped square antiprism is capsulated by the macrocyclic cavity environment forming the “lasso-type” protection. Relative photophysical properties of macrocyclic Sm(III) complexes are carefully investigated in solid-state, methanol solution, and doped PMMA film, and all these show characteristic emissions of the Sm(III) ion associated with satisfactory lifetimes and quantum yields in all media, which could be comparable to reported outstanding examples. Especially, the luminescence performance for this type of Sm(III) complex could be regulated in the solid state by the use of different functional groups in the pendant arm while it is not achieved in solution and the doped PMMA composite. High emitting and air-stable plastic materials could be obtained when these Sm(III) complexes are doped in PMMA with 0.1 wt % mixing ratio, and the corresponding maximum lifetime and quantum yield are 61.2 μs and 0.63% in the case of complex Sm-2a, respectively. We believe that these highly luminescent “lasso-type” Sm(III) complexes and doped PMMA composites are valuable references in the design of luminescent lanthanide(III) hybrid materials.

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Cocrystal engineering of molecular rearrangement: a “turn-on” approach for high-performance N-type organic semiconductors

Wang

Luo

Lin

et al. 2021

J. Mater. Chem. C

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The efficient sensitization of Sm(III) ion by a macrocycle with the matched cavity and energy level

et al. 2019

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A macrocyclic cavity microenvironment strategy for protecting lanthanide emitters from quenchers in solution

Yang

Lin

et al. 2018

Polyhedron

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Meng-Lu Lin

Peripheral halogenation engineering controls molecular stacking to enable highly efficient organic solar cells

Series of Highly Luminescent Macrocyclic Sm(III) Complexes: Functional Group Modifications Together with Luminescence Performances in Solid-State, Solution, and Doped Poly(methylmethacrylate) Film

Cocrystal engineering of molecular rearrangement: a “turn-on” approach for high-performance N-type organic semiconductors

The efficient sensitization of Sm(III) ion by a macrocycle with the matched cavity and energy level

A macrocyclic cavity microenvironment strategy for protecting lanthanide emitters from quenchers in solution

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