Solution processed Ag-In-S nanoparticles as light adsorber in ZnO for photovoltaic application

IF 0.8 Q4 NANOSCIENCE & NANOTECHNOLOGY Nanosystems: Physics, Chemistry, Mathematics Pub Date : 2023-08-30 DOI:10.17586/2220-8054-2023-14-4-454-466
K. Abinaya, P. Sharvanti, N. R. Yogamalar
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Abstract

A BSTRACT Nano-sized indium incorporated silver sulphide (Ag–In–S) nanocomposites were synthesized by simple wet chemical method as an electron transport layer in zinc oxide (ZnO) for high efficient photovoltaic (PV) cell. The inclusion of high conductivity indium ions in Ag 2 S will improve the facile electron transfer and the assembled hetero-structure features the solar light harvesting in PV cell. The powder X-ray diffraction (XRD) studies confirmed the formation of indium incorporated Ag 2 S ( AIS ) nanocomposites and ZnO/ AIS ( ZAIS ) compound nanocomposites crystallizing in pure monoclinic phase and mixed wurtzite hexagonal, monoclinic and tertiary phases respectively. The wide particle size distributions in ZAIS clearly revealed the adherence of AIS nanocomposites in ZnO lattice thus, promoting the light adsorption property. In addition, the tuning of the optical bandgap covering the entire solar spectrum (UV, visible, and infra-red regions), multiple-band electron transitions and hence, promoting the fast electron transportation are effectively achieved in ZAIS compound nanocomposites. With this simple positive approach, the PV cell efficiency is pushed forward with the In 3+ metal ion incorporation however; enhanced, enriched solar cell efficiency can be later tuned up with the detailed optimization studies.
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溶液处理Ag-In-S纳米粒子作为光伏应用的ZnO光吸附剂
摘要采用简单湿化学方法合成了一种纳米铟掺杂的硫化银(Ag-In-S)纳米复合材料,作为高效光伏电池中氧化锌(ZnO)的电子传输层。在Ag 2s中加入高导电性的铟离子,可以提高Ag 2s的电子转移便捷性,组装的异质结构具有光伏电池太阳能光收集的特点。粉末x射线衍射(XRD)研究证实了铟掺杂Ag 2s (AIS)纳米复合材料和ZnO/ AIS (ZAIS)复合纳米复合材料的形成,分别以纯单斜相和混合纤锌矿六方相、单斜相和三级相结晶。纳米复合材料在ZnO晶格中的广泛粒径分布揭示了纳米复合材料在ZnO晶格中的粘附性,从而提高了纳米复合材料的光吸附性能。此外,在ZAIS复合纳米材料中,有效地实现了覆盖整个太阳光谱(紫外、可见光和红外区域)的光学带隙的调谐,多波段电子跃迁,从而促进了电子的快速传递。通过这种简单的正极方法,光伏电池的效率随着in3 +金属离子的加入而提高;增强的、丰富的太阳能电池效率可以在以后通过详细的优化研究进行调整。
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来源期刊
Nanosystems: Physics, Chemistry, Mathematics
Nanosystems: Physics, Chemistry, Mathematics NANOSCIENCE & NANOTECHNOLOGY-
CiteScore
1.80
自引率
11.10%
发文量
64
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