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Cocrystallization of Binary Silver Clusters Into Supramolecular Assembly to Regulate Aggregation‐Induced Emission and Thermally Activated Delayed Fluorescence

Wu Liang, Hai‐Ling Wang, Ping Lu, Pei‐Yu Liao, Wei Deng, Jian‐Hua Jia, Ming‐Liang Tong

2025Aggregate12 citationsDOIOpen Access PDF

Abstract

ABSTRACT Aggregation‐induced emission (AIE) and thermally activated delayed fluorescence (TADF) are two optoelectronic properties with great potential for applications. However, metal nanoclusters exhibiting both AIE and TADF characteristics have not been extensively studied. This study investigates a binary cocrystal system based on silver nanoclusters—Ag 6 (Et 2 NCS 2 ) 6 ·[Ag 11 (AdmS) 3 (Et 2 NCS 2 ) 6 ] 2 ( 1‐Ag 6 ·(Ag 11 ) 2 ), aiming to explore the synergistic effects between flexible‐alkyl dithiol and rigid monothiol ligands. Due to the introduction of Ag 6 structures, the system exhibits enhanced stability and modulated optical properties. The binary tricluster 1‐Ag 6 ·(Ag 11 ) 2 demonstrates significant AIE behavior, with an approximately 15‐fold increase in intensity when the water volume fraction ( f w ) is 60%. Single‐crystal X‐ray diffraction analysis indicates that the enhanced AIE effect originates from intercluster hydrogen bonding interactions, which drive the self‐assembly of sub‐clusters and form hierarchical structures, thereby suppressing ligand rotation. In addition, the system exhibits the TADF phenomenon in the temperature range of 100−175 K. In order to further investigate the effect of ligand variations on optical properties, two unitary clusters, Ag 11 (AdmS) 3 (Et 2 NCS 2 ) 6 ( 2‐Ag 11 ‐AS ) and Ag 11 ( t BuS) 3 (Et 2 NCS 2 ) 6 ( 3‐Ag 11 ‐BS ), are synthesized, and their roles in regulating optoelectronic properties are explored through ligand exchange reactions. This study provides important insights for the development of efficient luminescent materials with AIE and TADF properties, highlighting the critical roles of ligand exchange and structural configuration.

Topics & Concepts

Aggregation-induced emissionSupramolecular chemistryFluorescenceBinary numberSupramolecular assemblySelf-assemblyMaterials scienceNanotechnologyChemistryPhotochemistryCrystallographyCrystal structurePhysicsOpticsArithmeticMathematicsNanocluster Synthesis and ApplicationsGold and Silver Nanoparticles Synthesis and ApplicationsLuminescence and Fluorescent Materials
Cocrystallization of Binary Silver Clusters Into Supramolecular Assembly to Regulate Aggregation‐Induced Emission and Thermally Activated Delayed Fluorescence | Litcius