Divalent manganese (Mn2+, 3d5) charge transfer energies and vacuum-referred binding energies in inorganic compounds

Q2 Engineering
J.J. Schuyt , G.V.M. Williams , S.V. Chong
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引用次数: 0

Abstract

Ongoing efforts to develop a predictive model governing the host-referred binding energies (HRBEs) and vacuum-referred binding energies (VRBEs) of transition metal dopants in inorganic host compounds are stymied by a lack of cross-compound data sets that capture transitions between the dopant ions and the valence and conduction bands of the hosts. Herein, we have compiled data consistent with Mn2+ charge transfer processes in 53 different compounds, spanning fluorides, oxides, chlorides, bromides, and nitrides. By assigning these transitions to Mn2+ → conduction band metal-to-metal charge transfer and combining these energies with the binding energies of electrons in the valence and conduction bands of the various hosts, we have calculated the HRBEs and VRBEs of the Mn2+ ion across a range of compounds. We show that variations in the Mn2+ VRBE are small relative to the variations in the VRBE of the valence and conduction bands, which manifests an approximately linear relationship between the Mn2+ HRBE and the bandgap energy of host compounds. We investigated the relationship between the Mn2+ VRBE and the various structures of the host compounds and showed that the chemical shift experienced by the Mn2+ ion depends on the electronegativity of the ligand, the Mn2+ coordination, and the Mn-ligand bond lengths in a predictable manner.

无机化合物中的二价锰(Mn2+,3d5)电荷转移能和真空参考结合能
由于缺乏能捕捉掺杂离子与宿主价带和导带之间转变的跨化合物数据集,目前正在开发的无机宿主化合物中过渡金属掺杂剂的宿主参考结合能(HRBE)和真空参考结合能(VRBE)预测模型受到了阻碍。在这里,我们汇编了 53 种不同化合物中与 Mn2+ 电荷转移过程一致的数据,这些化合物包括氟化物、氧化物、氯化物、溴化物和氮化物。通过将这些跃迁归结为 Mn2+ → 传导带金属对金属的电荷转移,并将这些能量与不同宿主的价带和传导带中电子的结合能相结合,我们计算出了一系列化合物中 Mn2+ 离子的 HRBE 和 VRBE。我们发现,相对于价带和导带的 VRBE 变化,Mn2+ VRBE 的变化很小,这表明 Mn2+ HRBE 与宿主化合物的带隙能之间存在近似线性关系。我们研究了 Mn2+ VRBE 与宿主化合物各种结构之间的关系,结果表明 Mn2+ 离子经历的化学位移以可预测的方式取决于配体的电负性、Mn2+ 配位和 Mn 配体键长度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Optical Materials: X
Optical Materials: X Engineering-Electrical and Electronic Engineering
CiteScore
3.30
自引率
0.00%
发文量
73
审稿时长
91 days
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