Compressometer based method for measuring converse electrostriction in polymers

1999 Annual Report Conference on Electrical Insulation and Dielectric Phenomena (Cat. No.99CH36319) Pub Date : 1999-10-17 DOI:10.1109/CEIDP.1999.804657

R. Yimnirun, S. Eury, V. Sundar, P. Moses, R. Newnham

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引用次数: 4

Abstract

Electrostriction is the fundamental mechanism of electromechanical coupling in all insulator materials. In this work, the electrostrictive coefficients of several polymers were measured by a converse method. A modified compressometer for resolving fractional changes in capacitance of the order of 10/sup -6/ was used. A highly sensitivity capacitance bridge GenRad 1615 was coupled with a lock-in amplifier to detect attofarad (10/sup -18/) level capacitance changes caused by cyclic uniaxial stresses on samples. Measurements were done at room temperature with an electrical frequency of 1 kHz and a mechanical frequency of 0.4 Hz. We found negative electrostriction coefficients for the polymers tested. The influences of crystallinity, glass reinforcement, and blending were observed to affect the electrostriction behavior due to the fact that electrostriction is mainly governed by the elastic properties in low-permittivity polymers. Using these recent data, along with widely accepted data on ferroelectric materials and soft polymers, the linear relationship between electrostriction coefficient (Q) and the ratio of elastic compliance and dielectric permittivity (s//spl epsiv//sub 0//spl rho//sub r/) was confirmed. This leads to an effective way to predict the electrostriction coefficient in dielectric materials.

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基于压缩计的聚合物反电伸缩测量方法

电致伸缩是所有绝缘子材料机电耦合的基本机理。本文采用逆向法测量了几种聚合物的电致伸缩系数。使用了一种改进的压缩计，用于分辨10/sup -6/量级的电容的分数变化。高灵敏度电容桥GenRad 1615与锁相放大器耦合，可检测样品上循环单轴应力引起的阿法拉(10/sup -18/)级电容变化。测量在室温下进行，电频率为1khz，机械频率为0.4 Hz。我们发现测试聚合物的电致伸缩系数为负。由于电致伸缩主要由低介电常数聚合物的弹性特性决定，因此观察到结晶度、玻璃增强和共混对电致伸缩行为的影响。利用这些最新数据，以及广泛接受的铁电材料和软聚合物的数据，证实了电伸缩系数Q与弹性柔度和介电常数之比(s//spl epsiv//sub 0//spl rho//sub r/)之间的线性关系。这为预测介电材料的电致伸缩系数提供了一种有效的方法。

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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1999 Annual Report Conference on Electrical Insulation and Dielectric Phenomena (Cat. No.99CH36319)

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