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
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.