Charge storage and retention in electret dielectric layers for energy harvesting applications

2014 IEEE 9th IberoAmerican Congress on Sensors Pub Date : 2014-12-29 DOI:10.1109/IBERSENSOR.2014.6995520

A. Diaz-Ballester, S. Castillo-Anguera, J. M. Rafí, R. Gómez-Martínez, G. Abadal, E. Figueras, J. Plaza, J. Esteve, M. Mudarra, J. C. Cañadas

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Abstract

By providing a permanent electric polarization, electrets have a wide range of applications in different fields like sensors and actuators, energy harvesting or biomedicine. Stable electrets with silicon-based compatible technology are particularly pursued. In this work, different dielectric layer stacks, including SiO2, Si3N4, AL2O3 and AlN, are evaluated in terms of charge storage and retention. The corona charging characteristics are analyzed and local micro-breakdowns of the dielectric layers are observed for critical electric fields in the range of 6-7 MV/cm. A hexamethyldisilazane (HMDS) surface treatment is confirmed to provide an effective protection for electret charge retention. Unfortunately for potential applications involving liquids, the charge is found to vanish after electret surface soaking with either deionized water or ethanol. In principle, deeper charge storage in the electret dielectric layers could be achieved by using an alternative method based on charge injection by means of a direct contact. The results of first attempts with such alternative technique are also reported.

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能量收集应用中驻极体介电层的电荷储存和保持

通过提供永久的电极化，驻极体在传感器和执行器、能量收集或生物医学等不同领域有广泛的应用。稳定的驻极体与硅基兼容技术是特别追求的。在这项工作中，不同的介电层堆叠，包括SiO2, Si3N4, AL2O3和AlN，在电荷存储和保留方面进行了评估。在6 ~ 7 MV/cm的临界电场范围内，分析了电晕充电特性，观察了介质层的局部微击穿。六甲基二矽氮烷(HMDS)表面处理可有效保护驻极体电荷保留。不幸的是，对于涉及液体的潜在应用，发现用去离子水或乙醇浸泡驻极体表面后电荷消失。原则上，在驻极体介电层中更深的电荷存储可以通过使用基于直接接触的电荷注入的替代方法来实现。本文还报道了采用这种替代技术进行首次尝试的结果。

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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2014 IEEE 9th IberoAmerican Congress on Sensors

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