Cluster approach for the density functional theory study of organic cation vibrations in hybrid halide post-perovskite 3-cyanopyridinium lead tribromide

IF 2.4 3区化学 Q2 SPECTROSCOPY Journal of Raman Spectroscopy Pub Date : 2023-11-12 DOI:10.1002/jrs.6618

Irina V. Krauklis, Anna Yu Samsonova, Nikita I. Selivanov, Yury V. Kapitonov, Yuri V. Chizhov

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Abstract

Internal vibrations of organic cations in halide perovskites and their analogues could be used to study the crystal structure of these novel semiconductor materials. In this work, we have studied the vibration properties of the 3-cyanopyridinium (3cp⁺ = [3-CN-C5H5NH]⁺) cation in the hybrid organic–inorganic halide post-perovskite (3cp)PbBr₃. For DFT modeling of the experimental Raman spectrum, we have constructed three different models: free cation, minimal stoichiometric cluster and nanocluster. Calculations of a free cation adequately describe most of the internal vibrations. To describe high-wavenumber hydrogen stretching vibrations, and first of all N–H vibrations, it is necessary to use sufficiently large clusters. We show in the cluster approach for crystal field description that it is necessary to include in the cluster not only halogens but also their nearest environment. In this case, agreement with experiment is reached, and further considerations can be put forward about the strength of the hydrogen bond and its role in stabilising the crystal.

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用簇方法研究混合卤化物后过氧化物 3-氰基吡啶鎓三溴化铅中有机阳离子的振动

卤化物包晶石及其类似物中有机阳离子的内部振动可用于研究这些新型半导体材料的晶体结构。在这项工作中，我们研究了有机-无机混合卤化物后包晶 (3cp)PbBr3 中 3-氰基吡啶鎓（3cp+ = [3-CN-C5H5NH]+）阳离子的振动特性。为了对实验拉曼光谱进行 DFT 建模，我们构建了三种不同的模型：自由阳离子、最小化学计量簇和纳米簇。自由阳离子的计算充分描述了大部分内部振动。为了描述高波长氢伸缩振动，首先是 N-H 振动，必须使用足够大的团簇。我们在晶体场描述的簇方法中表明，在簇中不仅要包括卤素，还要包括其最近的环境。在这种情况下，就可以与实验达成一致，并可以进一步考虑氢键的强度及其在稳定晶体中的作用。

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来源期刊

Journal of Raman Spectroscopy 物理-光谱学

CiteScore

5.40

自引率

8.00%

发文量

185

审稿时长

3.0 months

期刊介绍： The Journal of Raman Spectroscopy is an international journal dedicated to the publication of original research at the cutting edge of all areas of science and technology related to Raman spectroscopy. The journal seeks to be the central forum for documenting the evolution of the broadly-defined field of Raman spectroscopy that includes an increasing number of rapidly developing techniques and an ever-widening array of interdisciplinary applications. Such topics include time-resolved, coherent and non-linear Raman spectroscopies, nanostructure-based surface-enhanced and tip-enhanced Raman spectroscopies of molecules, resonance Raman to investigate the structure-function relationships and dynamics of biological molecules, linear and nonlinear Raman imaging and microscopy, biomedical applications of Raman, theoretical formalism and advances in quantum computational methodology of all forms of Raman scattering, Raman spectroscopy in archaeology and art, advances in remote Raman sensing and industrial applications, and Raman optical activity of all classes of chiral molecules.