ZnO nanowires for photoelectric converter applications

IF 0.2 Q4 MATHEMATICS
V. Kidalov, N. Sosnytska, A. Dyadenchuk, R. Oleksenko
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引用次数: 1

Abstract

This work is focused on the creation and study of photosensitive structures based on zinc oxide nanofibers, which are promising for solar energy. Zinc oxide nanowires were obtained on the porous zinc selenide surface. The porous substrate was obtained by electrochemical etching of a low-resistance n-ZnSe plate (110) with a polished surface. Nanowires were deposited by radical-beam epitaxy. The annealing temperature was varied from 400° C to 500° C. The oxygen radical flux was 1.5∙1017 cm-2s-1. The process duration was 50 minutes. According to the scanning electron microscopy results, the nanowires length reaches 10 μm, the nanowires diameter is ~1 μm. The predominant X-ray diffraction reflex at 2θ=34.44° indicates the polycrystalline nature of the manufactured ZnO coatings with a wurtzite-type hexagonal lattice. The study of nanowires ZnO luminescence at room temperature contains an ultraviolet peak around 385 nm. This peak is related to the zinc oxide edge luminescence. Based on the fabricated structure, the design of the photoconverter was developed. The upper contact of the fabricated photoelectric converter was created by vacuum thermal sputtering of aluminum through a mask. The deposition was carried out at a substrate temperature of 200° C. Ohmic contacts were made using conductive silver paste. The reverse ohmic contact was formed by applying Al paste to the entire reverse side of the surface. The upper layer of the structure is an array of ZnO nanowires. The active base layer is ZnSe. The light volt-ampere characteristics of the obtained structure were measured in the AM 1.5 illumination mode. No-load voltage Uxx, short-circuit current Isc and the fill factor of the current-voltage characteristic FF of the solar element were measured. The efficiency of the manufactured photoconverter was 13.7 %.
光电变换器用ZnO纳米线
本文主要研究了基于氧化锌纳米纤维的光敏结构材料,该材料在太阳能领域具有广阔的应用前景。在多孔硒化锌表面制备了氧化锌纳米线。通过电化学刻蚀表面抛光的低电阻n-ZnSe板(110)得到多孔衬底。采用自由基束外延法制备纳米线。退火温度为400℃~ 500℃,氧自由基通量为1.5∙1017 cm-2s-1。进程持续时间为50分钟。扫描电镜结果显示,纳米线长度达到10 μm,纳米线直径为~1 μm。在2θ=34.44°处的主要x射线衍射反射表明制备的ZnO涂层具有纤锌矿型六边形晶格的多晶性质。纳米线ZnO在室温下的发光包含一个约385 nm的紫外峰。此峰与氧化锌边缘发光有关。在此基础上,进行了光电变换器的设计。所制备的光电转换器的上接点是通过掩模对铝进行真空热溅射形成的。在200℃的衬底温度下进行沉积,欧姆接触采用导电银膏。反向欧姆接触是通过在整个表面的背面涂铝膏形成的。该结构的上层是ZnO纳米线阵列。活性基础层为ZnSe。在AM 1.5照明模式下测量了所得结构的光伏安特性。测量了太阳能元件的空载电压Uxx、短路电流Isc和电流电压特性FF的填充系数。该光电转换器的效率为13.7%。
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
CiteScore
0.30
自引率
0.00%
发文量
11
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