通过大分子聚结实现石墨纤维的超高强度、模量和导电性。

Ultrahigh strength, modulus, and conductivity of graphitic fibers by macromolecular coalescence.

作者信息

Lee Dongju, Kim Seo Gyun, Hong Seungki, Madrona Cristina, Oh Yuna, Park Min, Komatsu Natsumi, Taylor Lauren W, Chung Bongjin, Kim Jungwon, Hwang Jun Yeon, Yu Jaesang, Lee Dong Su, Jeong Hyeon Su, You Nam Ho, Kim Nam Dong, Kim Dae-Yoon, Lee Heon Sang, Lee Kun-Hong, Kono Junichiro, Wehmeyer Geoff, Pasquali Matteo, Vilatela Juan J, Ryu Seongwoo, Ku Bon-Cheol

机构信息

Institute of Advanced Composite Materials, Korea Institute of Science and Technology (KIST), Wanju 55324, Republic of Korea.

Department of Advanced Materials Engineering, Center for Advanced Material Analysis, The University of Suwon, Suwon 18323, Republic of Korea.

出版信息

Sci Adv. 2022 Apr 22;8(16):eabn0939. doi: 10.1126/sciadv.abn0939.

DOI:10.1126/sciadv.abn0939

PMID:35452295

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9032978/

Abstract

Theoretical considerations suggest that the strength of carbon nanotube (CNT) fibers be exceptional; however, their mechanical performance values are much lower than the theoretical values. To achieve macroscopic fibers with ultrahigh performance, we developed a method to form multidimensional nanostructures by coalescence of individual nanotubes. The highly aligned wet-spun fibers of single- or double-walled nanotube bundles were graphitized to induce nanotube collapse and multi-inner walled structures. These advanced nanostructures formed a network of interconnected, close-packed graphitic domains. Their near-perfect alignment and high longitudinal crystallinity that increased the shear strength between CNTs while retaining notable flexibility. The resulting fibers have an exceptional combination of high tensile strength (6.57 GPa), modulus (629 GPa), thermal conductivity (482 W/m·K), and electrical conductivity (2.2 MS/m), thereby overcoming the limits associated with conventional synthetic fibers.

摘要

理论考量表明，碳纳米管（CNT）纤维的强度应该非常出色；然而，它们的力学性能值却远低于理论值。为了制备具有超高性能的宏观纤维，我们开发了一种通过单个纳米管聚结形成多维纳米结构的方法。将单壁或双壁纳米管束的高度取向湿纺纤维进行石墨化处理，以促使纳米管塌陷并形成多内壁结构。这些先进的纳米结构形成了相互连接、紧密堆积的石墨域网络。它们近乎完美的取向和高纵向结晶度提高了碳纳米管之间的剪切强度，同时保持了显著的柔韧性。由此得到的纤维具有高拉伸强度（6.57吉帕）、模量（629吉帕）、热导率（482瓦/米·开尔文）和电导率（2.2兆西门子/米）的优异组合，从而克服了传统合成纤维的相关限制。

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通过大分子聚结实现石墨纤维的超高强度、模量和导电性。

Ultrahigh strength, modulus, and conductivity of graphitic fibers by macromolecular coalescence.

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