A comprehensive DFT Study of the electronic structure and optical properties of Iodine-based halide double perovskites for photovoltaic applications

IF 3 3区 化学 Q3 CHEMISTRY, PHYSICAL
B. Mouhib , S. Dahbi , N. Baaalla , N. Tahiri , O. El Bounagui , A. El Mansouri , H. Ez-Zahraouy
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Abstract

This study aims to explore the electronic structure, thermodynamic, mechanical stability, and optical response of Iodine-based ordered vacancy double halide perovskite compounds through the application of density functional theory. The two compounds Cs2ZrI6 and Rb2ZrI6 exhibit thermodynamic stability, with displaying particularly notable. Moreover, analysis of the calculated coefficients of elastic stiffness confirms the mechanical stability of all materials under ambient pressure conditions. By using the Density Functional Theory with Spin-Orbit Coupling (SOC), it was observed that Cs2TeI6 and Rb2TeI6 possess an indirect band gap located between the X and L high-symmetry points, this show that Cs2TeI6, Rb2ZrI6, Cs2HfI6, and Rb2HfI6 are identified as direct semiconductor compounds. Moreover, the band gap values of X2YI6 (where X = Cs, Rb, and Y = Te, Zr, and Hf) exhibit an increasing trend as we progress along the alkali and transition metal elements in the periodic table, ranging from 1.422 eV for Cs2TeI6 to 2.465 eV for Rb2TeI6. Besides, the optical behavior of the visible light show that X2YI6 compounds have a high absorption of about 70%, reflectance of 30%, and a low transmittance. Thanks to their advantageous bandgap, enduring stabilities, and effective absorption of visible light, Cs2TeI6 and Rb2TeI6 hold significant promise for a wide range of electronic and optoelectronic applications, particularly in photovoltaics.

Abstract Image

用于光伏应用的碘基卤化物双包晶石的电子结构和光学特性的 DFT 综合研究
本研究旨在通过应用密度泛函理论,探索碘基有序空位双卤化物包晶化合物的电子结构、热力学、机械稳定性和光学响应。结果表明,Cs2ZrI6 和 Rb2ZrI6 这两种化合物具有热力学稳定性,其中 Cs2ZrI6 的显示尤为显著。此外,对弹性刚度系数的计算分析证实了所有材料在常压条件下的机械稳定性。利用自旋轨道耦合密度泛函理论(SOC),观察到 Cs2TeI6 和 Rb2TeI6 具有位于 X 和 L 高对称点之间的间接带隙,这表明 Cs2TeI6、Rb2ZrI6、Cs2HfI6 和 Rb2HfI6 被确定为直接半导体化合物。此外,X2YI6(其中 X = Cs、Rb,Y = Te、Zr 和 Hf)的带隙值随着元素周期表中碱金属和过渡金属元素的增加而呈上升趋势,从 Cs2TeI6 的 1.422 eV 到 Rb2TeI6 的 2.465 eV。此外,可见光的光学特性表明,X2YI6 化合物具有约 70% 的高吸收率、30% 的反射率和较低的透射率。由于 Cs2TeI6 和 Rb2TeI6 具有良好的带隙、持久的稳定性和对可见光的有效吸收,它们在广泛的电子和光电应用领域,尤其是在光伏领域,有着广阔的前景。
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来源期刊
CiteScore
4.20
自引率
10.70%
发文量
331
审稿时长
31 days
期刊介绍: Computational and Theoretical Chemistry publishes high quality, original reports of significance in computational and theoretical chemistry including those that deal with problems of structure, properties, energetics, weak interactions, reaction mechanisms, catalysis, and reaction rates involving atoms, molecules, clusters, surfaces, and bulk matter.
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