化学
双折射
极化率
水溶液
各向异性
液晶
单体
化学物理
光电子学
聚合物
化学工程
平面的
蒸发
极化(电化学)
工作(物理)
纳米技术
偏振器
碳纤维
面(心理学)
水介质
光子学
材料科学
领域(数学)
光学各向异性
光学
作者
Congcong Jin,Yang Li,Chong‐An Chen,Jihyun Lee,Chanhee Ko,Soo‐Yeon Lee,Kang Min Ok
摘要
Birefringent crystals play a pivotal role in advanced optics owing to their indispensable function in modulating polarized light. Progress in this field has been driven by the evolution of “material genes”, from small π-conjugated monomers to π-oligomers and ultimately to expanded π-motifs. However, the poor aqueous processability inherent to the hydrophobic nature of extended carbon or C–N skeletons remains a significant hurdle for industrial applications. Herein, we propose a sulfonated module aggregation strategy to simultaneously optimize optical anisotropy and enable aqueous processability. Using a mild evaporation method, we synthesized five 1,3,6,8-pyreneterasulfonate (PTS) salts exhibiting large birefringence values ranging from 0.558 to 0.811 @ 546 nm. Notably, Na2(4-HPyH)2(PTS)·H2O [(4-HPyH) = 4-hydroxypyridinium] combines a wide band gap (Eg = 3.05 eV), enhanced aqueous processability, and a record-high birefringence (Δn = 0.811 @ 546 nm) among all sulfate- and sulfonate-based compounds, establishing it as a highly promising birefringent material. Structurally, the incorporation of [4-HPyH] modules reduces the space available for coordinated and guest water molecules, thereby maximizing the packing density of birefringence-active modules while maintaining ideal alignment of both [4-HPyH] and [PTS] units within the lattice. High-accuracy quantum chemical calculations further reveal a compensation mechanism associated with the ring fusion process─the supralinear polarizability anisotropy effect─which produces a supralinear enhancement of polarizability anisotropy upon aggregation of planar π-modules. This work offers a new paradigm for designing aqueous-processable birefringent crystals and expands the theoretical framework for understanding supralinear enhancement of micro-optical properties via π-module polymerization.
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