Effect of Growth-Temperature on Morphology and Piezoelectric Characteristics of ZnS Nanostructure

2022 2nd International Conference on Power Electronics & IoT Applications in Renewable Energy and its Control (PARC) Pub Date : 2022-01-21 DOI:10.1109/PARC52418.2022.9726549

Siju Mishra, P. Supraja, R. R. Kumar, D. Haranath

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Abstract

In this work, it has been demonstrated the effect of growth temperatures viz. 140 °C and 160 °C on the morphology and piezoelectric characteristics of zinc sulfide nanosheets (ZnS-NS) grown on aluminium substrates. Here, we fabricated two nanogenerator devices based on two different growth temperatures. A piezoelectric nanogenerator (PND) device was developed using Indium doped Tin Oxide (ITO) coated PET (Polyethylene Terephthalate) substrate and ZnS coated Al foil as top and bottom electrodes. An increase in growth temperature has a greater influence on the aspect ratio of the ZnS-NS due to the presence of extra thermal energy leading to significant structural deformation which in turn allowed the growth temperature window for the ZnS nanosheets to be determined. The open-circuit voltage for the as-fabricated devices was ~400 mV and ~600 mV, respectively. For the first time, a methodical study was carried out in the ZnS-NS system for designing novel piezoelectric nanogenerators. Due to its simple, one-step synthesis process with low cost, and high output gain, we are very much interested to investigates the potential of a ZnS-based piezoelectric energy harvesting device that can scavenge biomechanical energy for next-generation flexible self-powered electronics devices, as well as a good replacement for ZnO nanosheets in 2D nanostructured based nanogenerator devices.

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生长温度对ZnS纳米结构形貌和压电特性的影响

在这项工作中，已经证明了生长温度(140°C和160°C)对铝衬底上生长的硫化锌纳米片(ZnS-NS)的形貌和压电特性的影响。在这里，我们基于两种不同的生长温度制作了两个纳米发电机器件。采用掺杂铟氧化锡(ITO)包覆PET(聚对苯二甲酸乙二醇酯)衬底和ZnS包覆Al箔作为上下电极，研制了一种压电纳米发电机(PND)器件。生长温度的升高对ZnS- ns长径比的影响更大，因为额外的热能会导致显著的结构变形，从而确定了ZnS纳米片的生长温度窗口。器件的开路电压分别为~400 mV和~600 mV。本文首次对ZnS-NS系统进行了系统的研究，用于新型压电纳米发电机的设计。由于其简单，一步合成过程成本低，输出增益高，我们非常有兴趣研究基于zns的压电能量收集装置的潜力，该装置可以为下一代柔性自供电电子设备清除生物机械能，以及在基于二维纳米结构的纳米发电机设备中替代ZnO纳米片的良好替代品。

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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来源期刊

2022 2nd International Conference on Power Electronics & IoT Applications in Renewable Energy and its Control (PARC)

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