网状结缔组织
发光
水溶液
水介质
抗生素
星团(航天器)
纳米技术
材料科学
环境化学
化学
计算机科学
有机化学
光电子学
医学
病理
程序设计语言
生物化学
作者
Tsukasa Irie,Kohki Sasaki,Mika Nozaki,Tokuhisa Kawawaki,Shuntaro Takahashi,Saikat Das,Yuichi Negishi
标识
DOI:10.26434/chemrxiv-2025-js25l
摘要
Silver cluster-assembled materials (SCAMs) represent a promising class of luminescent solids, uniting atomically precise metal core architectures with crystalline framework design for tunable optical performance. Despite offering enhanced structural integrity over discrete silver nanoclusters, their broader application—particularly in aqueous-phase sensing—remains constrained by limited chemical and structural stability. Herein, we report TUS 8, a two-dimensional SCAM constructed from dodecanuclear Ag12 nodes and 1,1′-sulfonyldiimidazole (SDI) linkers. Single-crystal X-ray diffraction reveals a (2,4)-connected network in the P21/c space group featuring slightly distorted, hollow cuboctahedral Ag12 cores capped by μ4-tert-butylthiolates and μ2-trifluoroacetates. These layers stack via noncovalent interactions, forming a chemically robust porous architecture. TUS 8 exhibits intense ultraviolet absorption (λex = 215 nm) and strong aqueous photoluminescence emission at 344 nm, with a mono-exponential lifetime of 4.62 ns and an absolute quantum yield of 26.3%, among the highest reported for silver-based MOFs in water. The rigid framework and Ag···Ag interactions suppress non-radiative decay to enhance luminescence performance in aqueous media, while the material’s retention of high crystallinity after immersion in various solvents underscores its chemical robustness. Leveraging these features, TUS 8 functions as a recyclable luminescent sensor for antibiotic detection in water. Distinct PL responses are observed for nitrofurans, nitroimidazoles, and chloramphenicol, with quenching constants up to 2.4 × 103 M⁻1 and detection limits as low as 311 µM. This study highlights the potential of cluster-based reticular design for creating durable, water-stable, and highly emissive sensing platforms.
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