Spectral study on the formation of a self-assembled mesoscopic supercoil

Supramolecular Science Pub Date : 1998-10-01 DOI:10.1016/S0968-5677(98)00115-1

W.S. Yang, R. Lu, X.D. Chai, N. Lu, S.G. Chen, Y.S. Jiang, Y.W. Cao, X.Y. Tang, T.J. Li

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引用次数: 3

Abstract

Molecular recognition directing self-assembly of two complementary molecular components, 5-(4-dodecyloxybenzylidene)-2,4,6-(1H,3H)-pyrimidinetrione (B) and 4-amino-2,6-didodecylamino-1,3,5-triazine (M), was found to form a mesoscopic supercoil structure with length of several tens of μm and diameter of ca. 300 nm. Fluorescence spectral studies show that it takes more than 1200 h for the self-assembling process to reach the equilibrium in chloroform. It was suggested that in this system with positive cooperation, at least two steps were involved in the self-assembling process. First, supramolecular tapes, cyclic hexamers, are formed based on the network of triple complementary hydrogen bonds between B and M. Second, π-aromatic stacking and van der Waals interactions drive further the assembling of tapes into more complex nanometric strand. The coiling of the strands results in the formation of the supercoil structure.

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自组装介观超线圈形成的光谱研究

分子识别引导互补分子组分5-(4-十二烷基氧基苄基)-2,4,6-(1H,3H)-嘧啶三酮(B)和4-氨基-2,6-二十二烷基氨基-1,3,5-三嗪(M)的自组装，形成了长度为几十μm，直径约为300 nm的介孔超线圈结构。荧光光谱研究表明，在氯仿中，自组装过程需要1200 h以上才能达到平衡。有人建议，在这个积极合作的系统中，自组装过程至少涉及两个步骤。首先，基于B和m之间的三个互补氢键网络形成了超分子带，即环状六聚体。其次，π-芳族堆叠和范德华相互作用进一步推动了带组装成更复杂的纳米链。股的盘绕导致超级线圈结构的形成。

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Supramolecular Science

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