Thermal Diffusivity of Ti3C2Tx@C Nanocoils

Journal of Advanced Thermal Science Research Pub Date : 2021-12-27 DOI:10.15377/2409-5826.2021.08.7

Yeti Li, Fen Wu, Siqi Zhao, C. Deng

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Abstract

Ti3C2Tx MXene is an emerging 2D material with excellent electrical and electrochemical properties. Carbon Nanocoil (CNC) is a quasi 1D material with unique helical morphology, which shows remarkable advantages in mechanical and electromagnetic properties. In this work, we designed a Ti3C2Tx@C nanocoil (CMNC) by coating Ti3C2Tx flakes on the surface of CNC for better application performance. The thermophysical properties of single CMNCs were investigated using a transient eletrothermall (TET) technique. The average room temperature thermal diffusivity and thermal conductivity of CMNCs were measured to be 8×10-6 m2/s and 15.6 W/m K, which are one order of magnitude higher than those of CNCs, due to successful coating of MXene on the surface of CNC. However, enhancement of electrical properties brought by MXene coating is much smaller than those of thermal properties. Variable temperature characterization from 298 to 334 K reveals an increasing trend of thermal diffusivity and thermal conductivity with temperature increasing, which is attributed to the interaction and heat transfer between MXene and CNCs. MXene coating provides better thermal management performance for practical applications of CNCs, such as wave absorbing.

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Ti3C2Tx@C纳米线圈的热扩散系数

Ti3C2Tx MXene是一种新兴的二维材料，具有优异的电学和电化学性能。碳纳米线圈(CNC)是一种具有独特螺旋形态的准一维材料，在机械性能和电磁性能方面具有显著的优势。本文通过在CNC表面涂覆Ti3C2Tx薄片来设计Ti3C2Tx@C纳米线圈(CMNC)，以获得更好的应用性能。利用瞬态电热(TET)技术研究了单个cnc的热物理性质。在CNC表面成功涂覆MXene后，CNC的平均室温热扩散率和导热系数分别为8×10-6 m2/s和15.6 W/m K，比CNC高出一个数量级。然而，MXene涂层带来的电学性能的增强远远小于热学性能的增强。在298 ~ 334 K范围内的变温表征表明，随着温度的升高，MXene的导热系数和导热系数呈增加趋势，这是由于MXene与cnc之间的相互作用和热传递所致。MXene涂层为cnc的实际应用提供了更好的热管理性能，例如吸波。

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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Journal of Advanced Thermal Science Research

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