Screening Libraries of Semifluorinated Arylene Bisimides to Discover and Predict Thermodynamically Controlled Helical Crystallization

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• 作者：Ming-Shou Ho ; Benjamin E. Partridge ; Hao-Jan Sun ; Dipankar Sahoo ; Pawaret Leowanawat ; Mihai Peterca ; Robert Graf ; Hans W. Spiess ; Xiangbing Zeng ; Goran Ungar ; Paul A. Heiney ; Chain-Shu Hsu ; Virgil Percec
• 刊名：ACS Combinatorial Science
• 出版年：2016
• 出版时间：December 12, 2016
• 年：2016
• 卷：18
• 期：12
• 页码：723-739
• 全文大小：1301K
• ISSN：2156-8944

文摘

Synthesis, structural, and retrostructural analysis of a library containing 16 self-assembling perylene (PBI), 1,6,7,12-tetrachloroperylene (Cl₄PBI), naphthalene (NBI), and pyromellitic (PMBI) bisimides functionalized with environmentally friendly AB₃ chiral racemic semifluorinated minidendrons at their imide groups via m = 0, 1, 2, and 3 methylene units is reported. These semifluorinated compounds melt at lower temperatures than homologous hydrogenated compounds, permitting screening of all their thermotropic phases via structural analysis to discover thermodynamically controlled helical crystallization from propeller-like, cogwheel, and tilted molecules as well as lamellar-like structures. Thermodynamically controlled helical crystallization was discovered for propeller-like PBI, Cl₄PBI and NBI with m = 0. Unexpectedly, assemblies of twisted Cl₄PBIs exhibit higher order than those of planar PBIs. PBI with m = 1, 2, and 3 form a thermodynamically controlled columnar hexagonal 2D lattice of tilted helical columns with intracolumnar order. PBI and Cl₄PBI with m = 1 crystallize via a recently discovered helical cogwheel mechanism, while NBI and PMBI with m = 1 form tilted helical columns. PBI, NBI and PMBI with m = 2 generate lamellar-like structures. 3D and 2D assemblies of PBI with m = 1, 2, and 3, NBI with m = 1 and PMBI with m = 2 exhibit 3.4 Å π–π stacking. The library approach applied here and in previous work enabled the discovery of six assemblies which self-organize via thermodynamic control into 3D and 2D periodic arrays, and provides molecular principles to predict the supramolecular structure of electronically active components.