The Role of Annealing Treatment on Crystallographic, Optical, and Electrical Features of Bi2O3 Thin Films Prepared Using Reactive Plasma Sputtering Technology

IF 3.9 Q2 NANOSCIENCE & NANOTECHNOLOGY
S. J. Beden, Hassan A. Dumboos, M. K. Ismael, Mohanad Kadhim Mejbel
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Abstract

Bismuth oxide (Bi2O3) has attracted considerable research interest in test thin films made utilizing the reactive plasma sputtering (RPS) technology-assisted annealing treatment, allowing the development of diverse BixOx thin films. SEM, phase X-ray diffraction patterns, UV-Vis spectrometers, and D.C. two-probes are used to identify the crystallographic structure and assess the films’ optical-electrical properties. The XRD examination showed that forming Bi2O3 films with an amorphous to multiphase crystalline structure for sputtering time of 40 min was due to soda glass substrate temperature at a range of 30–35°C. Thin films of Bi2O3 crystal structures improved with annealing heat treatment at 200, 300, 400, and 500°C. Yet the formation of crystalline phase (β-Bi2O3 with δ-Bi2O3) Bi2O3 nanostructures occurred at higher temperatures. SEM images showed transparent particles highly affected by annealing temperatures. The nanostructures were about 102–510 nm long, and the diameter was 50–100 nm. The Bi2O3 film optical band gaps and nanostructures ranged from 2.75 to 3.05 eV. The annealing temperature differences affected the crystallite sizes, optical band gaps, and surface roughness. The findings showed that these differences caused the phase transition in Bi2O3 structures. The electrical calculation revealed that the electrical conductivity improved with annealing temperatures of 150–250°C while declining with temperature (300–500)°C with typical semiconductor films.
退火处理对反应等离子溅射技术制备的Bi2O3薄膜的晶体学、光学和电学特性的影响
氧化铋(Bi2O3)在利用反应等离子溅射(RPS)技术辅助退火处理的测试薄膜方面引起了相当大的研究兴趣,从而可以开发出各种BixOx薄膜。利用扫描电子显微镜、相x射线衍射图、紫外可见光谱和直流双探针鉴定了薄膜的晶体结构,并评估了薄膜的光电性能。XRD分析表明,在30 ~ 35℃的碱玻璃衬底温度下,溅射时间为40 min,形成了具有非晶到多相结构的Bi2O3薄膜。在200、300、400和500℃退火热处理后,Bi2O3薄膜的晶体结构得到改善。然而,在较高的温度下会形成晶相(β-Bi2O3与δ-Bi2O3)的纳米结构。SEM图像显示透明颗粒受退火温度影响较大。纳米结构长102 ~ 510 nm,直径50 ~ 100 nm。Bi2O3薄膜的光学带隙和纳米结构在2.75 ~ 3.05 eV之间。退火温度的差异影响了晶体尺寸、光学带隙和表面粗糙度。结果表明,这些差异导致了Bi2O3结构的相变。电学计算表明,典型半导体薄膜的电导率在150 ~ 250℃退火温度下提高,在300 ~ 500℃退火温度下下降。
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来源期刊
Journal of Nanotechnology
Journal of Nanotechnology NANOSCIENCE & NANOTECHNOLOGY-
CiteScore
5.50
自引率
2.40%
发文量
25
审稿时长
13 weeks
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