Raman Effect Studies of Electrochemical Synthesized Quartz Crystal of Poly-O-Phenylenediamine for Piezoelectric Application

Physical Science International Journal Pub Date : 2022-07-30 DOI:10.9734/psij/2022/v26i330315

Ndukwe O. Francis, A. Nwokoye, E. Amalu, O. O. Anyanor

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Abstract

Microelectronics arose from the desire for miniaturization of electrical devices, while Nano-electronics arose from subsequent study. Researchers have developed and modeled energy harvesting technologies based on the conservation law of energy over the last two decades to produce an alternative power source for small size electronics (nano-electronics) and low power electronic devices that can replace traditional power sources like batteries. The ambient energy, which is typically in the form of solar, thermal, vibrational, and other types, can be converted into a variety of different forms. Electrical energy can be harvested from vibrational energy in materials and other man-made materials using piezoelectric, electromagnetic, electrostatic, and nano-electric generators. Poly-o-phenylenediamine (PoPD) Quartz (silicon dioxide) Crystals were electrochemically produced at varied percentage ratios of silicon dioxide and Poly-O-Phenylenediamine samples in this study (sample A represents 20:80 percent, sample B with 50:50 percent, and sample C has 60:40 percent respectively). The Raman Effect and Scanning Electron Microscopic (SEM) analysis were used to characterize the material and forecast its Piezoelectric effect. All of the samples have their maximum peak record at Raman shift of 2872cm-1, however the Raman intensity varies. Sample A produced a peak intensity of 1250, Sample B produced a peak intensity of 1700, and Sample C produced a peak intensity of 2700. As the doping concentration of silicon dioxide increases, the Raman peak intensity for Poly-o-Phenylenediamine doped with silicon dioxide increases. The SEM images show that Sample A forms a fine cluster with little or no distinctive morphology, Sample B is ball-shaped with grain-like structure, and Sample C shows a flat, thin leaf-like shape. From sample A to C, the intra-particle separation rises, which corresponds to an increase in SiO2 concentration.

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压电用电化学合成聚邻苯二胺石英晶体的拉曼效应研究

微电子学源于对电子设备小型化的渴望，而纳米电子学则源于随后的研究。在过去的二十年里，研究人员基于能量守恒定律开发并模拟了能量收集技术，以生产一种可替代小型电子产品(纳米电子产品)和低功耗电子设备的替代电源，可以取代传统的电源，如电池。环境能量通常以太阳能、热能、振动和其他类型的形式存在，可以转换成各种不同的形式。利用压电、电磁、静电和纳米发电机，可以从材料和其他人造材料的振动能量中获取电能。本研究以不同比例的二氧化硅和聚邻苯二胺样品(样品A为20:80 %，样品B为50:50 %，样品C为60:40 %)电化学制备了聚邻苯二胺(PoPD)石英(二氧化硅)晶体。利用拉曼效应和扫描电镜(SEM)对材料进行了表征，并对其压电效应进行了预测。所有样品的拉曼位移峰值均为2872cm-1，但拉曼强度不同。样品A的峰强度为1250，样品B的峰强度为1700，样品C的峰强度为2700。随着二氧化硅掺杂浓度的增加，掺杂二氧化硅的聚邻苯二胺的拉曼峰强度增大。SEM图像显示，样品A形成细小的簇状结构，几乎没有明显的形貌;样品B呈球状，具有颗粒状结构;样品C呈扁平的薄叶状结构。从A样品到C样品，颗粒内分离增大，对应于SiO2浓度的增大。

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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Physical Science International Journal

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