Encapsulation and Evolution of Polyynes Inside Single-Walled Carbon Nanotubes

Nanomaterials Pub Date : 2024-06-02 DOI:10.3390/nano14110966

Kunpeng Tang, Yinong Li, Yingzhi Chen, Weili Cui, Zhiwei Lin, Yifan Zhang, Lei Shi

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Abstract

Polyyne is an sp-hybridized linear carbon chain (LCC) with alternating single and triple carbon–carbon bonds. Polyyne is very reactive; thus, its structure can be easily damaged through a cross-linking reaction between the molecules. The longer the polyyne is, the more unstable it becomes. Therefore, it is difficult to directly synthesize long polyynes in a solvent. The encapsulation of polyynes inside carbon nanotubes not only stabilizes the molecules to avoid cross-linking reactions, but also allows a restriction reaction to occur solely at the ends of the polyynes, resulting in long LCCs. Here, by controlling the diameter of single-walled carbon nanotubes (SWCNTs), polyynes were filled with high yield below room temperature. Subsequent annealing of the filled samples promoted the reaction between the polyynes, leading to the formation of long LCCs. More importantly, single chiral (6,5) SWCNTs with high purity were used for the successful encapsulation of polyynes for the first time, and LCCs were synthesized by coalescing the polyynes in the (6,5) SWCNTs. This method holds promise for further exploration of the synthesis of property-tailored LCCs through encapsulation inside different chiral SWCNTs.

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单壁碳纳米管内聚乙炔的封装和演化

聚乙烯是一种具有单碳碳键和三碳碳键交替的杂化线性碳链（LCC）。聚乙烯具有很强的反应性，因此很容易通过分子间的交联反应破坏其结构。聚乙烯越长越不稳定。因此，很难在溶剂中直接合成长聚炔。将聚炔封装在碳纳米管中，不仅可以稳定分子，避免交联反应，还能使限制反应只发生在聚炔的末端，从而得到长的 LCC。在这里，通过控制单壁碳纳米管（SWCNTs）的直径，在室温以下就能高产率地填充聚炔。随后对填充样品进行退火处理，促进了聚炔之间的反应，从而形成了长形 LCC。更重要的是，研究人员首次使用高纯度的单手性（6,5）SWCNTs 成功封装了多炔，并通过在（6,5）SWCNTs 中凝聚多炔合成了长链氯化石蜡。这种方法有望进一步探索通过在不同手性的 SWCNTs 内封装合成具有特定性质的 LCC。

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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Nanomaterials

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