Valence Band Modulation Using Cationic Filled p Orbitals toward p-Type Conduction

IF 3.2 2区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

Crystal Growth & Design Pub Date : 2025-03-04 DOI:10.1021/acs.cgd.5c0001210.1021/acs.cgd.5c00012

Hiroshi Mizoguchi*, Satoru Matsuishi, Hiroyo Segawa, Noriko Saito and Hideo Hosono*,

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引用次数: 0

Abstract

p-Type conduction is difficult in wide-gap compound semiconductors, such as transparent oxides. Anionic p orbitals primarily constituting the valence band maximum (VBM) are localized owing to their highly electronegative nature, which gives rise to a large ionization potential (Ip), leading to a difficulty in hole doping into the VBM. Here, we report a new approach to VBM modulation through the covalent interaction with filled cationic p orbitals. LaN is taken as an example. Pushing the anionic valence band (VB) to VBM by σ interaction in N–La chains between the N 2p VB and the filled La p orbitals decreases Ip and enhances the dispersion of VBM, leading to a direct-type band gap. Cationic p states (La 5p⁶) located energetically near the VB and linear coordination of La–N chains present in rock-salt-type crystal structures are keys to making the N p–La p covalent interaction strong.

We report a new approach to valence band maximum (VBM) modulation in wide-gap compound semiconductors such as transparent oxides through the covalent interaction with filled cationic p orbitals. LaN is taken as an example. Pushing the anionic valence band (VB) to VBM by σ interaction in N−La linear chains between the N 2p VB and the filled La p orbitals decreases ionization potential and enhances the dispersion of VBM, leading to a direct-type band gap.

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来源期刊

Crystal Growth & Design 化学-材料科学：综合

CiteScore

6.30

自引率

10.50%

发文量

650

审稿时长

1.9 months

期刊介绍： The aim of Crystal Growth & Design is to stimulate crossfertilization of knowledge among scientists and engineers working in the fields of crystal growth, crystal engineering, and the industrial application of crystalline materials. Crystal Growth & Design publishes theoretical and experimental studies of the physical, chemical, and biological phenomena and processes related to the design, growth, and application of crystalline materials. Synergistic approaches originating from different disciplines and technologies and integrating the fields of crystal growth, crystal engineering, intermolecular interactions, and industrial application are encouraged.