A theoretical investigation on the structure stability, electronic structures, optical properties, and transport properties of Zintl compounds CsZn4P3 and CsZn4As3

IF 3.2 3区化学 Q2 CHEMISTRY, INORGANIC & NUCLEAR

Journal of Solid State Chemistry Pub Date : 2024-08-28 DOI:10.1016/j.jssc.2024.124976

Yang Xue , Changqing Lin , Binyuan Huang , Huibing He , Dan Huang , Clas Persson

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Abstract

The present study investigates the structure stability, electronic structures, and optical properties of Zintl compounds CsZn4P₃ and CsZn₄As₃ by first-principles calculations. An assessment of the phonon dispersion curves and elastic constants indicate both dynamic and mechanical stability for the both compounds. By employing the HSE06 hybrid functional, both compounds display direct bandgap with widths of 0.93 eV for CsZn₄P₃ and 0.66 eV for CsZn₄As₃. Furthermore, an analysis of the dielectric constant, refractive index, extinction coefficient, and energy loss as functions of photon energy is conducted to study the optical properties. Based on the semi-classical Boltzmann transport theory and the Slack's equation, a large Seebeck coefficient and minimum lattice thermal conductivity are obtained for CsZn₄As₃, which result in a figure of merit value of 0.79 at 700 K. These findings underscore the potential of CsZn₄As₃ as a promising candidate for future research and development in the realm of thermoelectric materials.

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关于锌化合物 CsZn4P3 和 CsZn4As3 的结构稳定性、电子结构、光学特性和传输特性的理论研究

本研究通过第一性原理计算研究了锌化合物 CsZn4P3 和 CsZn4As3 的结构稳定性、电子结构和光学特性。对声子色散曲线和弹性常数的评估表明，这两种化合物具有动态和机械稳定性。通过使用 HSE06 混合函数，两种化合物都显示出直接带隙，CsZn4P3 的带隙宽度为 0.93 eV，CsZn4As3 的带隙宽度为 0.66 eV。此外，还分析了介电常数、折射率、消光系数和能量损失与光子能量的函数关系，以研究其光学特性。基于半经典波尔兹曼输运理论和斯拉克方程，CsZn4As3 获得了较大的塞贝克系数和最小的晶格热导率，从而在 700 K 时获得了 0.79 的优点值。

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来源期刊

Journal of Solid State Chemistry 化学-无机化学与核化学

CiteScore

6.00

自引率

9.10%

发文量

848

审稿时长

25 days

期刊介绍： Covering major developments in the field of solid state chemistry and related areas such as ceramics and amorphous materials, the Journal of Solid State Chemistry features studies of chemical, structural, thermodynamic, electronic, magnetic, and optical properties and processes in solids.