Density functional theory study of two-dimensional hybrid organic-inorganic perovskites: frontier level alignment and chirality-induced spin splitting

AAPPS Bulletin Pub Date : 2024-08-02 DOI:10.1007/s43673-024-00125-7

Ruyi Song, Rundong Zhao

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Abstract

Perovskites are a class of semiconductors initially recognized for their exceptional efficiency in solar cell applications. Subsequent research has revealed their diverse and attractive optoelectronic properties. Over the last decades, molecule-level engineering attempts toward the original three-dimensional (“3D”) perovskites have led to the emergence of two-dimensional (“2D”) layered crystals and introduced extensive compositional, structural, and electronic tunability through the incorporation of various organic cations to form hybrid perovskite systems. Consequently, we concentrated on the theoretical investigation of innovative and complex 2D hybrid organic-inorganic perovskites using density functional theory (DFT). A DFT-based simulation protocol has been developed, enabling the efficient simulation of hybrid perovskite systems and providing accurate explanations and predictions of various experimental phenomena. This account article summarizes the recent in-depth DFT study of the structural, electronic, and spin-related properties of 2D hybrid organic-inorganic perovskites.

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二维有机-无机杂化过氧化物的密度泛函理论研究：前沿水平排列和手性诱导的自旋分裂

过氧化物是一类半导体，最初因其在太阳能电池应用中的卓越效率而得到认可。随后的研究揭示了它们多样而诱人的光电特性。在过去的几十年中，针对原始三维（"3D"）包晶的分子级工程尝试导致了二维（"2D"）层状晶体的出现，并通过加入各种有机阳离子形成混合包晶系统，引入了广泛的组成、结构和电子可调性。因此，我们专注于利用密度泛函理论（DFT）对创新而复杂的二维有机-无机杂化包光体进行理论研究。基于 DFT 的模拟协议已经开发出来，能够高效模拟混合包晶体系，并对各种实验现象提供准确的解释和预测。这篇文章总结了最近对二维杂化有机-无机包晶的结构、电子和自旋相关性质进行的深入 DFT 研究。

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来源期刊

AAPPS Bulletin

CiteScore

8.20

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0.00%

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