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表面大分子有机结构的分层与顺序生长研究进展

Recent Advances of Hierarchical and Sequential Growth of Macromolecular Organic Structures on Surface.

作者信息

Pigot Corentin, Dumur Frédéric

机构信息

Aix Marseille Univ, CNRS, ICR UMR 7273, F-13397 Marseille, France.

出版信息

Materials (Basel). 2019 Feb 22;12(4):662. doi: 10.3390/ma12040662.

DOI:10.3390/ma12040662
PMID:30813327
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6416628/
Abstract

The fabrication of macromolecular organic structures on surfaces is one major concern in materials science. Nanoribbons, linear polymers, and porous nanostructures have gained a lot of interest due to their possible applications ranging from nanotemplates, catalysis, optoelectronics, sensors, or data storage. During decades, supramolecular chemistry has constituted an unavoidable approach for the design of well-organized structures on surfaces displaying a long-range order. Following these initial works, an important milestone has been established with the formation of covalent bonds between molecules. Resulting from this unprecedented approach, various nanostructures of improved thermal and chemical stability compared to those obtained by supramolecular chemistry and displaying unique and unprecedented properties have been developed. However, a major challenge exists: the growth control is very delicate and a thorough understanding of the complex mechanisms governing the on-surface chemistry is still needed. Recently, a new approach consisting in elaborating macromolecular structures by combining consecutive steps has been identified as a promising strategy to elaborate organic structures on surface. By designing precursors with a preprogrammed sequence of reactivity, a hierarchical or a sequential growth of 1D and 2D structures can be realized. In this review, the different reaction combinations used for the design of 1D and 2D structures are reported. To date, eight different sequences of reactions have been examined since 2008, evidencing the intense research activity existing in this field.

摘要

在表面制备大分子有机结构是材料科学中的一个主要关注点。纳米带、线性聚合物和多孔纳米结构因其在纳米模板、催化、光电子学、传感器或数据存储等方面的潜在应用而备受关注。几十年来,超分子化学已成为在表面设计具有长程有序的有序结构的一种必不可少的方法。在这些初步工作之后,随着分子间共价键的形成,一个重要的里程碑得以确立。这种前所未有的方法产生了各种与通过超分子化学获得的结构相比具有更高热稳定性和化学稳定性且展现出独特和前所未有的性质的纳米结构。然而,一个重大挑战仍然存在:生长控制非常精细,仍然需要深入了解支配表面化学的复杂机制。最近,一种通过结合连续步骤来构建大分子结构的新方法已被确定为在表面构建有机结构的一种有前景的策略。通过设计具有预编程反应序列的前体,可以实现一维和二维结构的分级或顺序生长。在这篇综述中,报道了用于设计一维和二维结构的不同反应组合。迄今为止,自2008年以来已经研究了八种不同的反应序列,证明了该领域存在的激烈研究活动。

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