用DFT探测Cs2OsX6 （X = Cl, Br， I）双钙钛矿：光催化水裂解和CO2还原的前景

IF 1.7 4区物理与天体物理 Q3 PHYSICS, CONDENSED MATTER

The European Physical Journal B Pub Date : 2025-06-16 DOI:10.1140/epjb/s10051-025-00979-2

Mohamed El Amine El Goutni, Abedrahmane Remil, Mokhtare Saidi, Mohamed Batouche, Taib Seddik

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引用次数: 0

摘要

本研究在WIEN2k计算框架下，利用密度泛函理论（DFT）对Cs2OsX6 （X = Cl, Br， I）空位有序双钙钛矿的结构、电子、机械和光学性质进行了全面的理论研究。通过计算总基态能、内聚能和形成能，系统评价了Cs2OsX6化合物的结构稳定性，揭示了Cs2OsX6化合物在环境条件和有利的合成条件下具有良好的稳定性。机械性能评估，包括柯西压力和泊松比，表明主要是延展性行为，表明优异的机械耐久性。利用Wu和Cohen广义梯度近似（WC-GGA）和trans - blaha改进的Becke-Johnson （tbj）方法进行的电子结构计算显示，半导体行为的直接带隙为1.98 eV (Cs2OsCl6), 1.68 eV （Cs2OsX6）和0.91 eV （Cs2OsI6）。光学性质分析表明，Cs2OsI6在可见光光谱中具有较强的吸收，表现出优越的光收集能力。随着卤化物原子尺寸的增大，激子结合能的计算结果呈下降趋势，表明载流子分离增强，复合速率降低。带边比对表明，Cs2OsCl6和Cs2OsX6适合水氧化，而Cs2OsI6具有CO2还原潜力。这些发现为Cs2OsX6钙钛矿在下一代光电和光催化器件中的设计和优化提供了坚实的理论基础，推动了可持续能源技术的发展。图形抽象

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Probing Cs2OsX6 (X = Cl, Br, I) double perovskites via DFT: prospects for photocatalytic water splitting and CO2 reduction

This study presents a comprehensive theoretical investigation of the structural, electronic, mechanical, and optical properties of Cs₂OsX₆ (X = Cl, Br, I) vacancy-ordered double perovskites using density functional theory (DFT) within the WIEN2k computational framework. The structural stability of Cs₂OsX₆ compounds was systematically evaluated through calculations of total ground state energy, cohesive energy, and formation energy, revealing remarkable stability under ambient conditions and favorable synthesis conditions. Mechanical property assessments, including Cauchy pressure and Poisson's ratio, indicated predominantly ductile behavior, suggesting excellent mechanical durability. Electronic structure calculations, performed using the Wu and Cohen generalized gradient approximation (WC-GGA) and the Tran–Blaha modified Becke–Johnson (TB-mBJ) methods, revealed semiconducting behavior with direct bandgaps of 1.98 eV (Cs₂OsCl₆), 1.68 eV (Cs₂OsX₆), and 0.91 eV (Cs₂OsI₆). Optical property analysis demonstrated strong absorption in the visible spectrum, with Cs₂OsI₆ exhibiting superior light-harvesting capabilities. Exciton binding energy calculations showed a decreasing trend with increasing halide atomic size, indicating enhanced charge carrier separation and reduced recombination rates. Band edge alignment suggested that Cs₂OsCl₆ and Cs₂OsX₆ are suitable for water oxidation, while Cs₂OsI₆ shows potential for CO₂ reduction. These findings provide a robust theoretical foundation for the design and optimization of Cs₂OsX₆ perovskites in next-generation optoelectronic and photocatalytic devices, advancing sustainable energy technologies.