化学
超分子化学
构象异构
高分子
分子
分子内力
分子动力学
分子构象
自组装
纳米技术
产量(工程)
金属
卤化物
化学物理
密度泛函理论
超分子组装
构象变化
分子识别
计算化学
结构母题
溶剂
分子开关
结晶学
折叠(DSP实现)
分子模型
设计要素和原则
作者
Zheng Zhang,Yun‐Hu Deng,Lao-Bang Wang,Yi Tan,Jian‐Ping Lang
摘要
Natural macromolecules achieve complexity by accessing multiple conformational states, but replicating such adaptability in synthetic systems remains a central challenge. Here, we present a cluster-mediated conformational assembly (CMCA) strategy for building adaptive molecular cages with stimuli-responsive dynamics. In this approach, two metal clusters, bridged by three flexible arylthioether ligands, 1,2-bis((pyridin-4-ylthio)methyl)benzene (bpmb), yield caged conformational assemblies (CCAs) that exhibit extensive structural diversity. Single-crystal X-ray diffraction resolved 20 conformers among 64 states predicted computationally, with interconversion directed by solvent polarity, halide binding, and guest encapsulation. Encapsulation further enables reversible switching between static and gyroscopic states, while stabilization relies on C-H···π, C-H···S, and cation···π interactions. Density functional theory (DFT) calculations map a near-degenerate energy landscape, underpinning the dynamic behavior. This cluster-based approach establishes a design principle for chemically addressable conformational adaptability, offering opportunities in molecular recognition, responsive materials, and supramolecular regulation.
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