MXene典型特性及其在碳纤维复合材料中应用的研究进展

崔美荣; 吕雅玲; 钱鑫; 郝梦圆; 张永刚; 沈江南

doi:10.14028/j.cnki.1003-3726.2024.24.231

您当前的位置：

首页 >

文章列表页 >

MXene典型特性及其在碳纤维复合材料中应用的研究进展

综述 | 更新时间：2025-01-06

- MXene典型特性及其在碳纤维复合材料中应用的研究进展
- Research Progress on Typical Characteristic of MXene and Its Application in Carbon Fiber Composites
- 高分子通报 2025年38卷第1期页码：58-74
- 作者机构：
  
  1.浙江工业大学化学工程学院，杭州 310014
  2.中国科学院宁波材料技术与工程研究所，碳纤维制备技术国家工程实验室，宁波 315201
- 作者简介：
  
  *钱鑫，E-mail: qx3023@nimte.ac.cn
- 基金信息：
  
  中国博士后科学基金面上项目(2023M733598);浙江省自然科学基金(Q24E030047)
- DOI：10.14028/j.cnki.1003-3726.2024.24.231
  中图分类号：
- 收稿日期：2024-08-10，
  
  录用日期：2024-09-25，
  
  网络出版日期：2024-11-15，
  
  纸质出版日期：2025-01-20
- 稿件说明：
移动端阅览
崔美荣, 吕雅玲, 钱鑫, 郝梦圆, 张永刚, 沈江南. MXene典型特性及其在碳纤维复合材料中应用的研究进展. 高分子通报, 2025, 38(1), 58–74.

Cui, M. R.; Lv, Y. L.; Qian, X. Hao, M. Y.; Zhang, Y, G. A.; Shen, J. N. Research progress on typical characteristic of Mxene and its application in caron fier composites. Polym. Bull. (in Chinese), 2025, 38(1), 58–74.
崔美荣, 吕雅玲, 钱鑫, 郝梦圆, 张永刚, 沈江南. MXene典型特性及其在碳纤维复合材料中应用的研究进展. 高分子通报, 2025, 38(1), 58–74. DOI： 10.14028/j.cnki.1003-3726.2024.24.231.

Cui, M. R.; Lv, Y. L.; Qian, X. Hao, M. Y.; Zhang, Y, G. A.; Shen, J. N. Research progress on typical characteristic of Mxene and its application in caron fier composites. Polym. Bull. (in Chinese), 2025, 38(1), 58–74. DOI： 10.14028/j.cnki.1003-3726.2024.24.231.

摘要

MXene作为一种新型二维(2D)过渡金属碳化物、氮化物或碳氮化物，具有优异的物理结构和优异的机械性能、导电性和磁学性能等，因此在电化学储能、微波吸收、电磁屏蔽等不同领域广泛应用。碳纤维(CF)经过热处理和高温氧化制备而成，导致表面光滑且缺乏活性基团，不利于碳纤维与基体间的粘附性，从而影响碳纤维复合材料的界面性能，通常引入纳米颗粒对CF表面改性，从而改善其粗糙度及赋予活性基团。因此，可以将MXene通过其范德华力或氢键、离子键和共价键引入CF表面，提高CF与基体的机械联锁效应，使复合材料的界面性质增强或实现功能化应用。本文总结了MXene的各种合成方法、结构特征和属性，讨论了采用不同技术在CF表面引入MXene进行改性增强复合材料界面性能及功能性应用的研究进展，最后提出了MXene面临的挑战和在碳纤维复合材料中应用的发展前景。

Abstract

As a new type of two-dimensional (2D) transition metal carbide

nitride or carbon nitride

MXene has excellent physical structure and excellent mechanical properties

electrical conductivity and magnetic properties

so it is widely used in different fields

such as electrochemical energy storage

microwave absorption

electromagnetic shielding. Carbon fiber (CF) is prepared by heat treatment and high temperature oxidation

resulting in smooth surface and lack of active groups

which is not conducive to the adhesion between carbon fiber and matrix

resulting in the interface properties of carbon fiber composite materials. Nano particles are usually introduced to modify the surface of carbon fiber to improve its roughness and give active groups. Therefore

MXene is introduced into CF surface through its van der Waals force or hydrogen

ionic and covalent bonds to improve the mechanical interlocking effect between CF and matrix

thereby improving the interface properties of the composite materials or enabling functional applications. In this review

various synthesis methods

structural characteristics and properties of MXene are summarized

and the research progress of introducing MXene into carbon fiber surface modification by different technologies to enhance the interface properties and functional applications of composites are discussed. Finally

the challenges faced by MXene and the development prospect of its application in carbon fiber composites are put forward.

关键词

Keywords

references

Naguib, M. ; Kurtoglu, M. ; Presser, V. ; Lu, J. ; Niu, J. J. ; Heon, M. ; Hultman, L. ; Gogotsi, Y. ; Barsoum, M. W . Two-dimensional nanocrystals produced by exfoliation of Ti 3 AlC 2 . Adv. Mater. , 2011 , 23 ( 37 ), 4248 – 4253 .

Lamiel, C. ; Hussain, I. ; Warner, J. H. ; Zhang, K. L . Beyond Ti-based MXenes: a review of emerging non-Ti based metal-MXene structure, properties, and applications . Mater. Today , 2023 , 63 , 313 – 338 .

丁姗姗 , 娄耀元 , 汪滨 , 王传春 , 王杰 , 马佳瑜 , 金旭 , 李秀艳 . MXene的制备及应用进展 . 高分子通报 , 2022 , ( 9 ), 16 – 26 .

Kumar, S. ; Kumari, N. ; Seo, Y . MXenes: versatile 2D materials with tailored surface chemistry and diverse applications . J. Energy Chem. , 2024 , 90 , 253 – 293 .

Yadav, M. ; Kumar, M. ; Sharma, A . Review of Ti 3 C 2 T x MXene nanosheets and their applications . ACS Appl. Nano Mater. , 2024 , 7 ( 9 ), 9847 – 9867 .

Anasori, B. ; Xie, Y. ; Beidaghi, M. ; Lu, J. ; Hosler, B. C. ; Hultman, L. ; Kent, P. R. C. ; Gogotsi, Y. ; Barsoum, M. W . Two-dimensional, ordered, double transition metals carbides (MXenes) . ACS Nano , 2015 , 9 ( 10 ), 9507 – 9516 .

Chen, Q. D. ; Yuan, S. F. ; Dai, J. H. ; Song, Y . Functionalized M 2 TiC 2 T x MXenes (M=Cr and Mo; T=F, O, and OH) as high performance electrode materials for sodium ion batteries . Phys. Chem. Chem. Phys. , 2021 , 23 ( 2 ), 1038 – 1049 .

Li, G. J. ; Natu, V. ; Shi, T. ; Barsoum, M. W. ; Titova, L. V . Two-dimensional MXenes Mo 2 Ti 2 C 3 T z and Mo 2 TiC 2 T z : microscopic conductivity and dynamics of photoexcited carriers . ACS Appl. Energy Mater. , 2020 , 3 ( 2 ), 1530 – 1539 .

Li, N. ; Zeng, Z. L. ; Zhang, Y. W. ; Chen, X. Z. ; Kong, Z. Z. ; Arramel, Li, Y. ; Zhang, P. ; Nguyen, B. S . Double transition metal carbides MXenes (D-MXenes) as promising electrocatalysts for hydrogen reduction reaction: Ab initio calculations . ACS Omega , 2021 , 6 ( 37 ), 23676 – 23682 .

Wan, Y. ; Takahashi, J . Development of carbon fiber-reinforced thermoplastics for mass-produced automotive applications in Japan . J. Compos. Sci. , 2021 , 5 ( 3 ), 86 .

Zhang, J. ; Lin, G. ; Vaidya, U. ; Wang, H . Past, present and future prospective of global carbon fibre composite developments and applications . Compos. Part B Eng. , 2023 , 250 , 110463 .

丁奇胜 , 谭晶 , 张政和 , 程礼盛 , 杨卫民 . 高取向度碳纤维原丝制备工艺研究进展 . 高分子通报 , 2023 , ( 3 ), 310 – 315 .

Peng, X. C. ; Wu, Y. F. ; Wei, Z. M . Research progress on the surface modification of carbon fiber . RSC Adv. , 2024 , 14 ( 6 ), 4043 – 4064 .

Li, J. ; Yang, Z. F. ; Huang, X. F. ; Zhao, Y. ; Li, X. ; Wei, W. F. ; Li, H. ; Wu, G. N . Interfacial reinforcement of composites by the electrostatic self-assembly of graphene oxide and NH 3 plasma-treated carbon fiber . Appl. Surf. Sci. , 2022 , 585 , 152717 .

Sasikumar, R. ; Babu, B. R. ; Subramanian, V. ; Jayavel, R . Multifunctionality of MWCNT modified carbon fiber reinforced thermoplastic composite, and reclaiming composite in the pursuit of sustainable energy storage applications: an experimental and numerical analysis . Compos. Sci. Technol. , 2024 , 248 , 110468 .

Xiong, K. ; Liu, F. ; Chen, T. ; Xiong, L . Facile and efficient grafting of graphene oxide onto carbon fiber with hyperbranched poly(thioether-yne) via click chemistry to improve interface and mechanical properties of composite . Surf. Interfaces , 2024 , 46 , 104038 .

Wang, Z. Y. ; Zhang, Y. Z. ; Sun, G. W. ; Gao, W. ; Wang, Y. L. ; Zhan, L . Improvement of carbon fiber/phenolic composite properties by low-loading graphene oxide and SiO 2 nanoparticles . Mater. Lett. , 2024 , 365 , 136400 .

Randall, J. D. ; Stojcevski, F. ; Djordjevic, N. ; Hendlmeier, A. ; Dharmasiri, B. ; Stanfield, M. K. ; Knorr, D. B. ; Tran, N. T. ; Varley, R. J. ; Henderson, L. C . Carbon fiber polypropylene interphase modification as a route to improved toughness . Compos. Part A Appl. Sci. Manuf. , 2022 , 159 , 107001 .

Naguib, M. ; Mashtalir, O. ; Carle, J. ; Presser, V. ; Lu, J. ; Hultman, L. ; Gogotsi, Y. ; Barsoum, M. W . Two-dimensional transition metal carbides . ACS Nano , 2012 , 6 ( 2 ), 1322 – 1331 .

Pinto, D. ; Anasori, B. ; Avireddy, H. ; Shuck, C. E. ; Hantanasirisakul, K. ; Deysher, G. ; Morante, J. R. ; Porzio, W. ; Alshareef, H. N. ; Gogotsi, Y . Synthesis and electrochemical properties of 2D molybdenum vanadium carbides-solid solution MXenes . J. Mater. Chem. A , 2020 , 8 ( 18 ), 8957 – 8968 .

Chen, X. ; Li, R. ; Li, B. ; Wang, J. ; Wang, T. ; Yan, F. X. ; Zhang, G. J . Achieving ultra-high ductility and fracture toughness in molybdenum via Mo 2 TiC 2 MXene addition . Mater. Sci. Eng. A , 2021 , 818 , 141422 .

Dhamodharan, D. ; Al-Harthi, M. A. ; Ramya, B. ; Bafaqeer, A. ; Alam, F . MXenes: a promising material with multifunctional applications . J. Environ. Chem. Eng. , 2024 , 12 ( 2 ), 112316 .

Ghidiu, M. ; Lukatskaya, M. R. ; Zhao, M. Q. ; Gogotsi, Y. ; Barsoum, M. W . Conductive two-dimensional titanium carbide ‘clay’ with high volumetric capacitance . Nature , 2014 , 516 ( 7529 ), 78 – 81 .

Bai, W. C. ; Shi, L. Y. ; Li, Z. H. ; Liu, D. ; Liang, Y. M. ; Han, B. C. ; Qi, J. ; Li, Y. Q . Recent progress on the preparation and application in photocatalysis of 2D MXene-based materials . Mater. Today Energy , 2024 , 41 , 101547 .

Mazinani, A. ; Rastin, H. ; Nine, M. J. ; Lee, J. ; Tikhomirova, A. ; Tung, T. T. ; Ghomashchi, R. ; Kidd, S. ; Vreugde, S. ; Losic, D . Comparative antibacterial activity of 2D materials coated on porous-titania . J. Mater. Chem. B , 2021 , 9 ( 32 ), 6412 – 6424 .

Venkateshalu, S. ; Cherusseri, J. ; Karnan, M. ; Kumar, K. S. ; Kollu, P. ; Sathish, M. ; Thomas, J. ; Jeong, S. K. ; Grace, A. N . New method for the synthesis of 2D vanadium nitride (MXene) and its application as a supercapacitor electrode . ACS Omega , 2020 , 5 ( 29 ), 17983 – 17992 .

Sun, K. Y. ; Wu, Y. Z. ; Xu, J. ; Xiong, W. F. ; Xu, W. ; Li, J. W. ; Sun, Z. Y. ; Lv, Z. Y. ; Wu, X. S. ; Jiang, Q. ; Cai, H. L. ; Shi, D. Q . Niobium carbide (MXene) reduces UHMWPE particle-induced osteolysis . Bioact. Mater. , 2022 , 8 , 435 – 448 .

He, H. T. ; Wang, J. K. ; Xia, Q. X. ; Wang, L. B. ; Hu, Q. K. ; Zhou, A. G . Effect of electrolyte on supercapacitor performance of two-dimensional molybdenum carbide (Mo 2 CT x ) MXene prepared by hydrothermal etching . Appl. Surf. Sci. , 2021 , 568 , 150971 .

Wu, Z. Y. ; Zhu, S. ; Bai, X. R. ; Liang, M. ; Zhang, X. ; Zhao, N. Q. ; He, C. N . One-step in situ synthesis of Sn-nanoconfined Ti 3 C 2 T x MXene composites for Li-ion battery anode . Electrochim. Acta , 2022 , 407 , 139916 .

Arole, K. ; Blivin, J. W. ; Bruce, A. M. ; Athavale, S. ; Echols, I. J. ; Cao, H. X. ; Tan, Z. Y. ; Radovic, M. ; Lutkenhaus, J. L. ; Green, M. J . Exfoliation, delamination, and oxidation stability of molten salt etched Nb 2 CT z MXene nanosheets . Chem. Commun. , 2022 , 58 ( 73 ), 10202 – 10205 .

Yin, T. ; Li, Y. ; Wang, R. H. ; Al-Hartomy, O. A. ; Al-Ghamdi, A. ; Wageh, S. ; Luo, X. L. ; Tang, X. ; Zhang, H . Synthesis of Ti 3 C 2 F x MXene with controllable fluorination by electrochemical etching for lithium-ion batteries applications . Ceram. Int. , 2021 , 47 ( 20 ), 28642 – 28649 .

Liew, J. ; Liu, L. ; Loh, K. H. ; Bashir, S. ; Ramesh, K. ; Ramesh, S . How viable are MXenes? Recent developments of MXene synthesis and its application in solid-state electrolytes . J. Energy Storage , 2024 , 84 , 110868 .

Wang, D. ; Zhou, C. K. ; Filatov, A. S. ; Cho, W. ; Lagunas, F. ; Wang, M. Z. ; Vaikuntanathan, S. ; Liu, C. ; Klie, R. F. ; Talapin, D. V . Direct synthesis and chemical vapor deposition of 2D carbide and nitride MXenes . Science , 2023 , 379 ( 6638 ), 1242 – 1247 .

Gandla, D. ; Zhuang, Z. L. ; Jadhav, V. V. ; Tan, D. Q . Lewis acid molten salt method for 2D MXene synthesis and energy storage applications: a review . Energy Storage Mater. , 2023 , 63 , 102977 .

Ajmal, Z. ; Qadeer, A. ; Khan, U. ; Bilal Hussain, M. ; Irfan, M. ; Mehmood, R. ; Abid, M. ; Djellabi, R. ; Kumar, A. ; Ali, H. ; Kalam, A. ; Al-Sehemi, A. G. ; Algarni, H. ; Al-Hadeethi, Y. ; Qian, J. ; Hayat, A. ; Zeng, H. Q . Current progresses in two-dimensional MXene-based framework: prospects from superficial synthesis to energy conversion and storage applications . Mater. Today Chem. , 2023 , 27 , 101238 .

Zhang, X. ; Zhang, Z. H. ; Zhou, Z . MXene-based materials for electrochemical energy storage . J. Energy Chem. , 2018 , 27 ( 1 ), 73 – 85 .

Tang, Q. ; Zhou, Z. ; Shen, P. W . Are MXenes promising anode materials for Li ion batteries? Computational studies on electronic properties and Li storage capability of Ti 3 C 2 and Ti 3 C 2 X 2 (X=F, OH) monolayer . J. Am. Chem. Soc. , 2012 , 134 ( 40 ), 16909 – 16916 .

Patil, A. M. ; Jadhav, A. A. ; Chodankar, N. R. ; Avatare, A. T. ; Hong, J. ; Dhas, S. D. ; Patil, U. M. ; Jun, S. C . Recent progress of MXene synthesis, properties, microelectrode fabrication techniques for microsupercapacitors and microbatteries energy storage devices and integration: A comprehensive review . Coord. Chem. Rev. , 2024 , 517 , 216020 .

Urbankowski, P. ; Anasori, B. ; Hantanasirisakul, K. ; Yang, L. ; Zhang, L. H. ; Haines, B. ; May, S. J. ; Billinge, S. J. L. ; Gogotsi, Y . 2D molybdenum and vanadium nitrides synthesized by ammoniation of 2D transition metal carbides (MXenes) . Nanoscale , 2017 , 9 ( 45 ), 17722 – 17730 .

Hong Ng, V. M. ; Huang, H. ; Zhou, K. ; Lee, P. S. ; Que, W. X. ; Xu, J. Z. ; Kong, L. B . Recent progress in layered transition metal carbides and/or nitrides (MXenes) and their composites: synthesis and applications . J. Mater. Chem. A , 2017 , 5 ( 7 ), 3039 – 3068 .

Shuck, C. E. ; Han, M. K. ; Maleski, K. ; Hantanasirisakul, K. ; Kim, S. J. ; Choi, J. ; Reil, W. E. B. ; Gogotsi, Y . Effect of Ti 3 AlC 2 MAX phase on structure and properties of resultant Ti 3 C 2 T x MXene . ACS Appl. Nano Mater. , 2019 , 2 ( 6 ), 3368 – 3376 .

Gao, L. F. ; Li, C. ; Huang, W. C. ; Mei, S. ; Lin, H. ; Ou, Q. ; Zhang, Y. ; Guo, J. ; Zhang, F. ; Xu, S. X. ; Zhang, H . MXene/polymer membranes: synthesis, properties, and emerging applications . Chem. Mater. , 2020 , 32 ( 5 ), 1703 – 1747 .

Shein, I. R. ; Ivanovskii, A. L . Graphene-like nanocarbides and nanonitrides of d metals (MXenes): synthesis, properties and simulation . Micro Nano Lett. , 2013 , 8 ( 2 ), 59 – 62 .

Tang, H. ; Wang, R. R. ; Shi, L. J. ; Sheremet, E. ; Rodriguez, R. D. ; Sun, J . Post-processing strategies for improving the electrical and mechanical properties of MXenes . Chem. Eng. J. , 2021 , 425 , 131472 .

Shariq, M. ; Alshehri, K. ; Mohammed Bouzgarrou, S. ; Kashif Ali, S. ; Alqurashi, Y. ; Hassan, K. F. ; Azooz, R. E . Progress in development of MXene-based nanocomposites for supercapacitor application—a review . FlatChem , 2024 , 44 , 100609 .

Cao, S. W. ; Shen, B. J. ; Tong, T. ; Fu, J. W. ; Yu, J. G . 2D/2D heterojunction of ultrathin MXene/Bi 2 WO 6 nanosheets for improved photocatalytic CO 2 reduction . Adv. Funct. Mater. , 2018 , 28 ( 21 ), 1800136 .

Kim, H. ; Anasori, B. ; Gogotsi, Y. ; Alshareef, H. N . Thermoelectric properties of two-dimensional molybdenum-based MXenes . Chem. Mater. , 2017 , 29 ( 15 ), 6472 – 6479 .

Tian, S. ; Zhou, K. ; Huang, C. Q. ; Qian, C. ; Gao, Z. B. ; Liu, Y. L . Investigation and understanding of the mechanical properties of MXene by high-throughput computations and interpretable machine learning . Extreme Mech. Lett. , 2022 , 57 , 101921 .

Bai, Y. L. ; Zhou, K. ; Srikanth, N. ; Pang, J. H. L. ; He, X. D. ; Wang, R. G . Dependence of elastic and optical properties on surface terminated groups in two-dimensional MXene monolayers: a first-principles study . RSC Adv. , 2016 , 6 ( 42 ), 35731 – 35739 .

Ibrahim, Y. ; Mohamed, A. ; Abdelgawad, A. M. ; Eid, K. ; Abdullah, A. M. ; Elzatahry, A . The recent advances in the mechanical properties of self-standing two-dimensional MXene-based nanostructures: deep insights into the supercapacitor . Nanomaterials , 2020 , 10 ( 10 ), 1916 .

Borysiuk, V. N. ; Mochalin, V. N. ; Gogotsi, Y . Molecular dynamic study of the mechanical properties of two-dimensional titanium carbides Ti n +1 C n (MXenes) . Nanotechnology , 2015 , 26 ( 26 ), 265705 .

Firestein, K. L. ; von Treifeldt, J. E. ; Kvashnin, D. G. ; Fernando, J. F. S. ; Zhang, C. ; Kvashnin, A. G. ; Podryabinkin, E. V. ; Shapeev, A. V. ; Siriwardena, D. P. ; Sorokin, P. B. ; Golberg, D . Young’s modulus and tensile strength of Ti 3 C 2 MXene nanosheets as revealed by in situ TEM probing, AFM nanomechanical mapping, and theoretical calculations . Nano Lett. , 2020 , 20 ( 8 ), 5900 – 5908 .

Lipatov, A. ; Alhabeb, M. ; Lu, H. D. ; Zhao, S. S. ; Loes, M. J. ; Vorobeva, N. S. ; Dall’Agnese, Y. ; Gao, Y. ; Gruverman, A. ; Gogotsi, Y. ; Sinitskii, A . Electrical and elastic properties of individual single-layer Nb 4 C 3 T x MXene flakes . Adv. Electron. Mater. , 2020 , 6 ( 4 ), 1901382 .

Zha, X. H. ; Yin, J. S. ; Zhou, Y. H. ; Huang, Q. ; Luo, K. ; Lang, J. J. ; Francisco, J. S. ; He, J. ; Du, S. Y . Intrinsic structural, electrical, thermal, and mechanical properties of the promising conductor Mo 2 C MXene . J. Phys. Chem. C , 2016 , 120 ( 28 ), 15082 – 15088 .

Li, Y. R. ; Lai, M. L. ; Hu, M. M. ; Zhao, S. J. ; Liu, B. ; Kai, J. J . Insights into electronic and magnetic properties of MXenes: from a fundamental perspective . Sustain. Mater. Technol. , 2022 , 34 , e00516 .

Ponce-Pérez, R. ; Guerrero-Sanchez, J. ; Gutierrez-Ojeda, S. J. ; Moreno-Armenta, M. G . Oxygen coverage effect on the magnetic properties of the Cr 2 NO x (0≤ x ≤2) MXene . ACS Appl. Electron. Mater. , 2021 , 3 ( 11 ), 4967 – 4976 .

Scheibe, B. ; Tadyszak, K. ; Jarek, M. ; Michalak, N. ; Kempiński, M. ; Lewandowski, M. ; Peplińska, B. ; Chybczyńska, K . Study on the magnetic properties of differently functionalized multilayered Ti 3 C 2 T x MXenes and Ti-Al-C carbides . Appl. Surf. Sci. , 2019 , 479 , 216 – 224 .

Yue, Y. L. ; Wang, B. W. ; Miao, N. X. ; Jiang, C. ; Lu, H. W. ; Zhang, B. W. ; Wu, Y. K. ; Ren, J. ; Wang, M . Tuning the magnetic properties of Zr 2 N MXene by biaxial strain . Ceram. Int. , 2021 , 47 ( 2 ), 2367 – 2373 .

Gao, L. F. ; Zhao, Y. M. ; Chang, X. H. ; Zhang, J. ; Li, Y. ; Wageh, S. ; Al-Hartomy, O. A. ; Al-Sehemi, A. G. ; Zhang, H. ; Ågren, H . Emerging applications of MXenes for photodetection: recent advances and future challenges . Mater. Today , 2022 , 61 , 169 – 190 .

Berdiyorov, G. R . Optical properties of functionalized Ti 3 C 2 T 2 (T=F, O, OH) MXene: first-principles calcu-lations . AIP Adv. , 2016 , 6 ( 5 ), 055105 .

Hantanasirisakul, K. ; Alhabeb, M. ; Lipatov, A. ; Maleski, K. ; Anasori, B. ; Salles, P. ; Ieosakulrat, C. ; Pakawatpanurut, P. ; Sinitskii, A. ; May, S. J. ; Gogotsi, Y . Effects of synthesis and processing on optoelectronic properties of titanium carbonitride MXene . Chem. Mater. , 2019 , 31 ( 8 ), 2941 – 2951 .

Zhang, H. J. ; Yang, G. ; Zuo, X. Q. ; Tang, H. B. ; Yang, Q. ; Li, G . Computational studies on the structural, electronic and optical properties of graphene-like MXenes (M 2 CT 2 , M=Ti, Zr, Hf; T=O, F, OH) and their potential applications as visible-light driven photocatalysts . J. Mater. Chem. A , 2016 , 4 ( 33 ), 12913 – 12920 .

Lashgari, H. ; Abolhassani, M. R. ; Boochani, A. ; Elahi, S. M. ; Khodadadi, J . Electronic and optical properties of 2D graphene-like compounds titanium carbides and nitrides: DFT calculations . Solid State Commun. , 2014 , 195 , 61 – 69 .

Shukla, M. ; Kumar, S. ; Kumar, V . Metal–MXenes interaction: adsorption, bonding, and role of delocalized chemical bonding. MXenes as Surface-Active Advanced Materials . Amsterdam: Elsevier , 2024 , 63 – 80 .

Hu, S. K. ; Han, P. ; Meng, C. ; Yu, Y. ; Han, S. L. ; Wang, H. Y. ; Wei, G. ; Gu, Z . Comparative study of different bonding interactions on the interfacial adhesion and mechanical properties of MXene-decorated carbon fiber/epoxy resin composites . Compos. Sci. Technol. , 2024 , 245 , 110352 .

Hu, Y. ; Pang, S. J. ; Yang, G. Y. ; Yao, X. M. ; Li, C. B. ; Jiang, J. J. ; Li, Y. J . MXene modified carbon fiber composites with improved mechanical properties based on electrophoretic deposition . Mater. Res. Bull. , 2022 , 150 , 111761 .

Xu, N. ; Chen, S. H. ; Li, Y. Z. ; Jiang, N. Y. ; Zheng, T. ; Goossens, N. ; Vleugels, J. ; Zhang, D. X. ; Seveno, D . A hybrid 1D/2D coating strategy with MXene and CNT towards the interfacial reinforcement of carbon fiber/poly(ether ether ketone) composite . Compos. Part B Eng. , 2022 , 246 , 110278 .

Ma, C. ; Ma, M. G. ; Si, C. L. ; Ji, X. X. ; Wan, P. B . Flexible MXene‐based composites for wearable devices . Adv. Funct. Mater. , 2021 , 31 ( 22 ), 2009524 .

Dharmasiri, B. ; Usman, K. A. S. ; Qin, S. A. ; Razal, J. M. ; Tran, N. T. ; Coia, P. ; Harte, T. ; Henderson, L. C . Ti 3 C 2 T x MXene coated carbon fibre electrodes for high performance structural supercapacitors . Chem. Eng. J. , 2023 , 476 , 146739 .

Liu, W. L. ; Guo, Y. Q. ; Lin, T. ; Peng, H. C. ; Yu, Y. P. ; Yang, F. ; Chen, S . High-performance supercapacitor electrodes of MXene/PANI/carbon fiber hybrid composites with 2D/0D/1D hierarchical nanostructures . J. Alloys Compd. , 2022 , 926 , 166855 .

Sun, L. ; Fu, Q. ; Pan, C. X . Hierarchical porous “skin/skeleton” -like MXene/biomass derived carbon fibers heterostructure for self-supporting, flexible all solid-state supercapacitors . J. Hazard. Mater. , 2021 , 410 , 124565 .

Khumujam, D. D. ; Kshetri, T. ; Singh, T. I. ; Kim, N. H. ; Lee, J. H . Fibrous asymmetric supercapacitor based on wet spun MXene/PAN fiber-derived multichannel porous MXene/CF negatrode and NiCo 2 S 4 electrodeposited MXene/CF positrode . Chem. Eng. J. , 2022 , 449 , 137732 .

Iqbal, A. ; Shahzad, F. ; Hantanasirisakul, K. ; Kim, M. K. ; Kwon, J. ; Hong, J. ; Kim, H. ; Kim, D. ; Gogotsi, Y. ; Koo, C. M . Anomalous absorption of electromagnetic waves by 2D transition metal carbonitride Ti 3 CNT x (MXene) . Science , 2020 , 369 ( 6502 ), 446 .

Verma, R. ; Thakur, P. ; Chauhan, A. ; Jasrotia, R. ; Thakur, A . A review on MXene and its’ composites for electromagnetic interference (EMI) shielding applications . Carbon , 2023 , 208 , 170 – 190 .

Yin, G. ; Wang, Y. ; Wang, W. ; Yu, D . Multilayer structured PANI/MXene/CF fabric for electromagnetic interference shielding constructed by layer-by-layer strategy. Colloids Surf . A Physicochem . Eng. Aspects , 2020 , 601 , 125047 .

Duan, N. M. ; Shi, Z. Y. ; Wang, Z. H. ; Zou, B. ; Zhang, C. P. ; Wang, J. L. ; Xi, J. R. ; Zhang, X. S. ; Zhang, X. Z. ; Wang, G. L . Mechanically robust Ti 3 C 2 T x MXene/carbon fiber fabric/thermoplastic polyurethane composite for efficient electromagnetic interference shielding applications . Mater. Des. , 2022 , 214 , 110382 .

Duan, Y. F. ; Fang, X. T. ; Zhang, Z. L. ; Sun, R. ; Hong, J. ; Ruan, F. T. ; Hu, Q. L. ; Xu, Z. Z . Lightweight, flexible rCEF@PPy/MXene for ultra-efficient EMI shielding felt with Joule heating performance . Mater. Lett. , 2023 , 341 , 134297 .

Cui, C. ; Guo, R. H. ; Ren, E. H. ; Xiao, H. Y. ; Zhou, M. ; Lai, X. X. ; Qin, Q. ; Jiang, S. X. ; Qin, W. F . MXene-based rGO/Nb 2 CT x /Fe 3 O 4 composite for high absorption of electromagnetic wave . Chem. Eng. J. , 2021 , 405 , 126626 .

Wang, X. W. ; Zhao, C. ; Li, C. P. ; Liu, Y. ; Sun, S. ; Yu, Q. L. ; Yu, B. ; Cai, M. R. ; Zhou, F . Progress in MXene-based materials for microwave absorption . J. Mater. Sci. Technol. , 2024 , 180 , 207 – 225 .

Wang, J. Q. ; Liu, L. ; Jiao, S. L. ; Ma, K. J. ; Lv, J. ; Yang, J. J . Hierarchical carbon fiber@MXene@MoS 2 core-sheath synergistic microstructure for tunable and efficient microwave absorption . Adv. Funct. Mater. , 2020 , 30 ( 45 ), 2002595 .

Han, X. P. ; Huang, Y. ; Gao, S. ; Zhang, G. Z. ; Li, T. H. ; Liu, P. B . A hierarchical carbon fiber@MXene@ZnO core-sheath synergistic microstructure for efficient microwave absorption and photothermal conversion . Carbon , 2021 , 183 , 872 – 883 .

Chao, M. ; Chu, N. ; Zhang, B. ; Luo, C. J. ; Yan, L. K . MXene/carbon fiber/polyimide composite aerogel for multifunctional microwave absorption . Compos. Commun. , 2024 , 46 , 101837 .

浏览量

682

下载量

CSCD

文章被引用时，请邮件提醒。

提交

工具集

关联资源

聚吡咯/铁基复合材料的制备及其应用

碳纤维增强热塑性复合材料摩擦性能研究进展

碳纳米管/聚合物基柔性电磁干扰屏蔽复合材料研究进展

聚吡咯包裹碳化硅气凝胶复合材料的电化学和吸波性能