Aza[10]CPP和n -甲基化酶[10]CPP的合成及C60结合

Fabian Schwer, Simon Zank, Markus Freiberger, Ramandeep Kaur, Stefan Frühwald, C. Robertson, A. Görling, T. Drewello, D. Guldi, Max von Delius
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引用次数: 2

摘要

在不断增长的应变碳纳米环和纳米带家族中,[10]CPP可以说是合成可及性和对C60的强结合亲和力之间的最佳折衷。在这项工作中,我们报道了两个含氮的[10]CPP类似物的合成,并系统地比较了这一小组结构相似的大环的结构、光电性能和C60结合亲和力。虽然Aza[10]CPP在C60结合方面比母体化合物高出大约一个数量级,但我们发现甲基化酶类似物的情况正好相反。瞬态吸收研究表明,光诱导电子从[10]CPP及其偶氮类似物到封装的C60客体容易发生转移。然而,n -甲基化衍生物未观察到电荷分离络合物的形成。这些见解将证明对应变纳米环在超分子化学和有机电子学中的进一步应用是有用的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Synthesis and C60 Binding of Aza[10]CPP and N-Methylaza[10]CPP
Within the growing family of strained carbon nanohoops and nanobelts, [10]CPP arguably offers the best compromise between synthetic accessibility and strong binding affinity for C60. In this work, we report the synthesis of two nitrogen-containing analogues of [10]CPP and we systematically compare the structure, optoelectronic properties and C60 binding affinities of this small set of structurally similar macrocycles. While Aza[10]CPP outcompetes the parent compound by approximately one order of magnitude in respect to C60 binding, we found that the reverse was true for the methylaza analogue. Transient absorption studies showed that photo-induced electron transfer occurred readily from [10]CPP and its aza-analogue to an encapsulated C60 guest. Formation of a charge separated complex was not observed however for the N-methylated derivative. These insights will prove useful for further applications of strained nanohoops in supramolecular chemistry and organic electronics.
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来源期刊
CiteScore
3.70
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0.00%
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0
审稿时长
12 weeks
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