在 400°C 基底温度下获得的 SbxSey 薄膜的结构和光学特性

IF 1.204 Q3 Energy

Applied Solar Energy Pub Date : 2024-03-23 DOI:10.3103/S0003701X23601552

T. M. Razykov, M. S. Tivanov, K. M. Kuchkarov, R. T. Yuldoshov, R. Khurramov, S. Muzafarova, D. S. Bayko

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引用次数: 0

摘要

摘要以锑（Sb）和硒（Se）为前驱体，通过化学分子束沉积法（CMBD）在钠钙玻璃上沉积了锑硒薄膜。通过分别控制锑（980 至 1025°C）和硒（415 至 470°C）的源温度，获得了不同成分比例的硒化锑薄膜。这项研究包括对 SbxSey 薄膜的元素和相组成以及晶体结构的全面分析。为此，研究人员采用了多种分析技术，包括能量色散 X 射线显微分析、原子力显微镜、拉曼光谱、X 射线衍射和扫描电子显微镜。通过使用分光光度计获取吸收光谱，确定了薄膜的带隙在 1.03-1.25 eV 之间。这有助于确定薄膜的光学特性，并进一步分析其潜在应用。研究了不同比例的 SbxSey 薄膜的物理性质。

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Structural and Optical Properties of Thin SbxSey Films Obtained at a Substrate Temperature of 400°C

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Structural and Optical Properties of Thin SbxSey Films Obtained at a Substrate Temperature of 400°C

Sb_xSe_y thin-films were deposited by chemical-molecular beam deposition (CMBD) on soda-lime glass from antimony (Sb) and selenium (Se) precursors. Due to the separate control of Sb (between 980 and 1025°C) and Se (between 415 and 470°C) source temperature, thin films of antimony selenide with different component ratios carry out obtained. The investigation encompassed a comprehensive analysis of the elemental and phase composition, like the crystal structure, of Sb_xSe_y films. To achieve this, a combination of analytical techniques was employed, including energy-dispersive X-ray microanalysis, atomic force microscopy, Raman spectroscopy, X-ray diffraction, and scanning electron microscopy. The bandgap of the films was ascertained in the region 1.03–1.25 eV through the acquisition of absorption spectra using a spectrophotometer. This enabled the determination of the films’ optical properties and facilitated further analysis of their potential applications. The physical properties of Sb_xSe_y films with various ratio were researched.

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来源期刊

Applied Solar Energy Energy-Renewable Energy, Sustainability and the Environment

CiteScore

2.50

自引率

0.00%

发文量

期刊介绍： Applied Solar Energy is an international peer reviewed journal covers various topics of research and development studies on solar energy conversion and use: photovoltaics, thermophotovoltaics, water heaters, passive solar heating systems, drying of agricultural production, water desalination, solar radiation condensers, operation of Big Solar Oven, combined use of solar energy and traditional energy sources, new semiconductors for solar cells and thermophotovoltaic system photocells, engines for autonomous solar stations.