MWCNTs涂层超快速制备纳米花Mg:ZnO薄膜的光学和电学性能

Bilge International Journal of Science and Technology Research Pub Date : 2022-03-22 DOI:10.30516/bilgesci.1060177

İ. KARADUMAN ER, Fatma Sarf, Emin Yakar

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引用次数: 0

摘要

通过快速化学浴将多壁碳纳米管(MWCNTs)包覆在ZnO种子层上。XRD分析表明，MWCNTs涂层的取向优先从高能(002)峰向低能(101)峰转变。Mg掺杂ZnO样品的平均晶粒尺寸为15 nm。MWCNTs涂层可使材料直径减小50%。SEM图像显示，在Mg:ZnO表面存在高累积的纳米花形态，并且MWCNTs包埋可以实现均匀的网状涂层，从而增加了活性表面积。两种膜的光吸收边缘没有明显差异，但MWCNTs涂层增加了直接带隙。由于Burstein-Moss效应，使用tac图的Mg:ZnO和Mg:ZnO/MWCNTs薄膜的带隙值分别为3.04 eV和3.34 eV。从FTIR光谱上看，样品的官能团未见明显变化。电学研究表明，MWCNTs降低了薄膜在室温下的电阻，Mg:ZnO和Mg:ZnO/MWCNTs薄膜的电阻分别为29.85和8.53 k。

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Tuning Optical and Electrical Properties of Ultra-Fast Prepared Nanoflower Mg:ZnO Films by MWCNTs Coating

Mg doped ZnO films were coated multi-walled carbon nanotubes (MWCNTs) via fast chemical bath onto ZnO seed layers. XRD analysis showed preferential orientation shift from high-energy (002) peak to low-energy (101) peak with MWCNTs coating. Average crystalline size of Mg doped ZnO samples are 15 nm. diameter and 50% percent reduction has been observed with MWCNTs coating. SEM images reveals the presence of high accumulative nanoflower forms on Mg:ZnO surfaces and homogenous net-shaped coating has been achieved by MWCNTs inclusion so active surface area may increase. No major difference of optical absorption edge is detected in both films however MWCNTs coating cause an increase direct band gap. Due to Burstein-Moss effect, Mg:ZnO and Mg:ZnO/MWCNTs films with using Tauc plot calculated band gap values are 3.04 eV and 3.34 eV, respectively. From FTIR spectra, no obvious change is not detected the functional groups of the samples. Electrical studies show that MWCNTs decrease the resistance and the resistance of films at room temperature were calculated 29.85 and 8.53 k for Mg:ZnO and Mg:ZnO/MWCNTs films , respectively.

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Bilge International Journal of Science and Technology Research

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