Chiral recognition via symmetry-dependent luminescence in zero-dimensional hybrid copper halides
Yi Wei, Yan Zhang, Yawen Li, Chen Li, Yuxuan Wang, Zhishan Luo, Yulian Liu, Huimin Kang, Xihan Chen, Zewei Quan
Abstract
Chiral recognition through fluorescence changes enables the rapid and sensitive determination of enantiomers. However, the rational design and synthesis of fluorescent probes for efficient chiral recognition remain a challenge. Here we present a novel platform for chiral recognition based on zero-dimensional hybrid copper halides with unique symmetry-dependent properties. The use of mesomeric 1,2-diaminocyclohexane (DACH) ligands promotes the formation of centrosymmetric, non-luminescent Cu2I64− units. The incorporation of enantiopure S- or R-DACH ligands into these mesomeric compounds breaks their symmetry, spontaneously transforming them into chiral compounds and generating Cu4I62− units that exhibit intense circularly polarized luminescence. Additionally, introducing opposite chiral ligands into these chiral compounds leads to the formation of racemic, non-luminescent CuI32− units, whereas the addition of same-chirality ligands preserves the structure and optical properties of the chiral Cu4I62− units. This enantioselective response by utilizing symmetry-dependent optical properties offers a pathway toward advanced chiral sensing technologies. Zero-dimensional hybrid copper halides show symmetry-dependent luminescence, enabling selective chiral recognition by coupling structural transformations with distinct optical responses.