单壁碳纳米管/乙烯基聚合物复合材料阻抗分析

A. Ilgaz
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引用次数: 1

摘要

研究了单壁碳纳米管/乙烯基(SWCNT/VE)玻璃纤维增强聚合物(GFRP)复合材料的阻抗特性。在300 K和420 K之间的不同温度下,阻抗测量作为10-2和107 Hz范围内频率的函数进行。得到复阻抗(Z*)实部和虚部的Bode和Nyquist图,并采用Cole-Cole方法解释阻抗特性。结果表明,随着温度的升高,材料的体电阻显著降低。利用复阻抗数据和试件尺寸计算了随频率变化的交流电导率。已经观察到,交流电流值符合琼舍尔幂定律。分析了不同温度下介电常数和损耗因子随外加频率的变化规律。由于Maxwell-Wagner-Sillars (MWS)效应,样品在低频区表现出较高的介电常数,但由于偶极子在高频时无法沿场方向旋转,导致介电常数降低。在我们的极限范围内,在损耗谱中没有观察到介电弛豫峰。从结果可以看出,介面极化和直流电导率对介电弛豫的贡献是由介面极化和直流电导率引起的。采用电模量的形式描述了swcnts /VE二元复合材料的电导率和介电弛豫过程。结果发现,随着温度的升高,得到的峰值向更高的频率移动。结果表明,峰值以下的频率区限定了移动电荷载流子的范围,峰值以上的频率区限定了移动电荷载流子的短距离电势阱。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Impedance Analysis of Single Walled Carbon Nanotube/Vinylester Polymer Composites
This study presents impedance characteristics of single walled carbon nanotube/vinylester (SWCNT/VE) glass fiber reinforced polymer (GFRP) composites. The impedance measurements were carried out as a function of the frequency over range of 10-2 and 107 Hz at various temperatures between 300 K and 420 K. Bode and Nyquist plots of real and imaginary parts of complex impedance (Z*) were obtained and Cole–Cole approach was used to interpret the impedance characteristics. The results indicated that the bulk resistance of the material decreases significantly as the temperature increases. The frequency-dependent AC conductivities were calculated using the complex impedance data and dimensions of specimen. It has been observed that the alternating current values are compatible with the Jonscher’s power law. The behavior of dielectric constant and loss factor at the various temperatures were analyzed as a function of applied frequency. While the sample exhibited high dielectric permittivity in the low frequency region with the Maxwell-Wagner-Sillars (MWS) effect, it was observed that the permittivity decreased as a result of the dipoles' inability to rotate themselves in the field direction at high frequencies. No dielectric relaxation peak was observed in the loss spectra in our limits. From the results, it can be said that the contribution to the dielectric relaxation is due to the interface polarization and DC conductivity. Electric modulus formalism was also used to describe the conductivity and dielectric relaxation processes of SWCNT/VE binary composite. It was found that the obtained peak maximums shifted to higher frequencies as the temperature increased. It is concluded that the frequency regime below the peak maximum defines the range of mobile charge carriers, and in the regime above the maximum, the charge carriers are limited to short distance potential wells.
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来源期刊
Kuwait Journal of Science & Engineering
Kuwait Journal of Science & Engineering MULTIDISCIPLINARY SCIENCES-
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