Pulsed laser deposition of ZnO and MoO3 as reflection prohibitors on photovoltaic cell substrate to enhance the efficiency

Q3 Engineering

Journal of Achievements in Materials and Manufacturing Engineering Pub Date : 2022-08-01 DOI:10.5604/01.3001.0016.1414

P. Selvan, D. Jebaraj, N. Hynes

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Abstract

With the ever-growing demand for conventional fuels, the improvement in the efficiency of the photovoltaic system is the need of the hour. Antireflection coatings enhance the availability of solar power by reducing the percentage of light reflected. A new coating has been developed to improve the solar cell's overall efficiency. This study focuses on enhancing the efficiency of the monocrystalline solar cell when a coating of ZnO-MoO3 is applied at a certain thickness. A layer of ZnO followed by MoO3 is deposited on a Silicon solar cell substrate using a Pulsed Laser Deposition process. Due to the transmissivity d between the two materials, they act as excellent antireflection coating. The layer thickness has been engineered to lie in the maximum absorption spectrum of monocrystalline silicon solar cells, which is between 400 and 800 nanometers. Based on the calculation of transmissivities for a given layer thickness of coating material, the coating has been done, and the efficiencies of the coated specimen were compared with the uncoated solar cell. The percentage improvement in the electrical efficiency of a single crystalline silicon solar cell with an anti-reflection coating at 1059 W/m2 is about 35.7%. Among the available antireflection coating materials, the combination that provides better efficiency when coated on top of a solar cell is hard to find. This anti-reflection coating could be a better solution to enhance the overall efficiency of the single crystalline silicon solar cell. Although ZnO and MoO3 coatings have been investigated separately for improvement in solar cell efficiency with varying levels of success, the hybrid coating of ZnO/MoO3 with a performance enhancement of 35.7% is a great leap.

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在光伏电池衬底上脉冲激光沉积ZnO和MoO3作为反射抑制剂以提高效率

随着对常规燃料需求的不断增长，提高光伏发电系统的效率是当务之急。抗反射涂层通过减少光的反射率来提高太阳能的可用性。一种新的涂层已经被开发出来，以提高太阳能电池的整体效率。本研究的重点是在一定厚度的ZnO-MoO3涂层下提高单晶太阳能电池的效率。采用脉冲激光沉积工艺在硅太阳能电池衬底上沉积了一层ZnO和MoO3。由于两种材料之间的透过率d，它们作为优秀的抗反射涂层。该层厚度已被设计为位于单晶硅太阳能电池的最大吸收光谱范围内，即400至800纳米之间。在计算给定涂层厚度下的透射率的基础上，进行了涂层，并将涂层样品与未涂层的太阳能电池的效率进行了比较。单晶硅太阳能电池在1059 W/m2下的电效率提高了约35.7%。在现有的抗反射涂层材料中，很难找到在太阳能电池顶部涂层的组合，从而提供更好的效率。这种抗反射涂层可能是提高单晶硅太阳能电池整体效率的更好解决方案。虽然ZnO和MoO3涂层分别研究了提高太阳能电池效率的方法，并取得了不同程度的成功，但ZnO/MoO3混合涂层的性能提高了35.7%，是一个巨大的飞跃。

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

Journal of Achievements in Materials and Manufacturing Engineering Engineering-Industrial and Manufacturing Engineering

CiteScore

2.10

自引率

0.00%

发文量

期刊介绍： The Journal of Achievements in Materials and Manufacturing Engineering has been published by the Association for Computational Materials Science and Surface Engineering in collaboration with the World Academy of Materials and Manufacturing Engineering WAMME and the Section Metallic Materials of the Committee of Materials Science of the Polish Academy of Sciences as a monthly. It has 12 points which was received during the evaluation by the Ministry of Science and Higher Education journals and ICV 2017:100 on the ICI Journals Master list announced by the Index Copernicus. It is a continuation of "Proceedings on Achievements in Mechanical and Materials Engineering" published in 1992-2005. Scope: Materials[...] Properties[...] Methodology of Research[...] Analysis and Modelling[...] Manufacturing and Processingv Biomedical and Dental Engineering and Materials[...] Cleaner Production[...] Industrial Mangement and Organisation [...] Education and Research Trends[...]