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Circularly polarized luminescence enhancement in rare-earth MOFs due to framework chirality and host–guest energy transfer

Tong Hao, Bei Xu, Xinchao Wang, Hongrui Zheng, Shangda Li, Fei Wang, Jian Zhang

2025Polyoxometalates17 citationsDOIOpen Access PDF

Abstract

Chiral metal-organic frameworks (CMOFs) incorporating rare-earth ions hold great promise for circularly polarized luminescence (CPL) applications due to their structural tunability and strong emission. Herein, we report two pairs of enantiomeric rare-earth CMOFs synthesized via direct self-assembly of optically pure 1,3-bis((<em>S</em>)- or (<em>R</em>)-1-carboxyethyl)-1<em>H</em>-imidazol-3-ium chloride ([L/D-(H<sub>2</sub>IDPA)⁺Cl⁻]) with lanthanide ions. The resulting Tb-based framework, <strong>L-Tb-1</strong>, exhibits intrinsic CPL with a dissymmetry factor (|<em>g</em><sub>lum</sub>|) of 0.016, attributed to efficient chirality transfer and the antenna effect. Upon introducing MnCl<sub>4</sub><sup>2</sup>⁻ as a luminescent guest into the framework channels, the CPL activity of <strong>L-Tb-2∙(MnCl<sub>4</sub><sup>2</sup></strong><strong>⁻</strong><strong>)</strong> is markedly enhanced, achieving a |<em>g</em><sub>lum</sub>| of 0.071. Control experiments and spectral analysis confirm that this enhancement arises from synergistic host-guest energy transfer and chiral transfer. This work demonstrates a modular strategy for constructing CPL-active rare-earth CMOFs and provides a general design principle for tuning chiroptical properties via host-guest interactions.

Topics & Concepts

Chirality (physics)LuminescenceRare earthEnergy transferHost (biology)Circular polarizationMaterials scienceOptoelectronicsNanotechnologyPhysicsChemical physicsOpticsBiologyEcologyParticle physicsQuarkMetallurgyMicrostripNambu–Jona-Lasinio modelChiral symmetry breakingCrystal Structures and PropertiesLuminescence Properties of Advanced MaterialsMagnetism in coordination complexes