Rb2XSbX'6 (X= Ag, Cu; X'= Cl, Br) 的结构、电子、光学和热电特性：Ab-initio 计算

IF 3.1 3区物理与天体物理 Q2 Engineering

Optik Pub Date : 2024-08-23 DOI:10.1016/j.ijleo.2024.172009

M. Bouzidi , M. Ziati , K. Belasfar , A. El Bachiri , M.M. El Hammoumi , A. Rmili , A. Louardi , A. El Kenz , H. Ez-Zahraouy , A. Benyoussef

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引用次数: 0

摘要

本研究采用密度泛函理论（DFT）和 Wien2k 代码，辅以玻尔兹曼输运理论，通过第一原理计算研究了无铅双卤化物包晶材料 Rb2XSbX'6 的电子、光学和热电特性。通过将 Rb2XSbX'6 中的 X 替换为 Ag 或 Cu，X'替换为 Cl 或 Br，我们发现了一些有趣的性质。Rb2AgSbBr6、Rb2AgSbCl6、Rb2CuSbCl6 和 Rb2CuSbBr6 分别显示出 1.18 eV、2.17 eV、1.22 eV 和 0.87 eV 的低间接带隙，以及在可见光区域的高吸收。所研究的化合物具有很高的结构稳定性和热力学稳定性，这可以从它们的高体积模量和负形成能得到证实。此外，在热电研究中还观察到了广泛的优点值。这些研究结果与之前的研究结果非常吻合，因此将所研究的材料定位为有望应用于可见光太阳能电池装置的候选材料。

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Structural, electronic, optical, and thermoelectric features of Rb2XSbX’6 (X= Ag, Cu; X’= Cl, Br): Ab-initio calculations

This study investigates the electronic, optical, and thermoelectric properties of lead-free double halide perovskite materials, Rb₂XSbX'₆, through first-principles calculations employing Density Functional Theory (DFT) and the Wien2k code, complemented by Boltzmann transport theory. By substituting X with Ag or Cu and X’ with Cl or Br in Rb₂XSbX’₆, we uncover interesting properties. Rb₂AgSbBr₆, Rb₂AgSbCl_6, Rb₂CuSbCl_6, and Rb₂CuSbBr₆ exhibit low indirect band gaps of 1.18 eV, 2.17 eV, 1.22 eV, and 0.87 eV, respectively, alongside high absorption in the visible region. The studied compounds sustained a high level of structural and thermodynamic stability, which was confirmed by their high bulk modulus and negative formation energy. Furthermore, extensive values were observed for the figure of merit in the thermoelectric study. Given the strong agreement with previous research, these findings position the investigated materials as promising candidates for visible-light solar cell device applications.

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来源期刊

Optik 物理-光学

CiteScore

6.90

自引率

12.90%

发文量

1471

审稿时长

46 days

期刊介绍： Optik publishes articles on all subjects related to light and electron optics and offers a survey on the state of research and technical development within the following fields: Optics: -Optics design, geometrical and beam optics, wave optics- Optical and micro-optical components, diffractive optics, devices and systems- Photoelectric and optoelectronic devices- Optical properties of materials, nonlinear optics, wave propagation and transmission in homogeneous and inhomogeneous materials- Information optics, image formation and processing, holographic techniques, microscopes and spectrometer techniques, and image analysis- Optical testing and measuring techniques- Optical communication and computing- Physiological optics- As well as other related topics.