Spin-orbit coupling and spin-polarized electronic structures of Janus vanadium-dichalcogenide monolayers: first-principles calculations
Phonon and spintronic structures of monolayered Janus vanadium-dichalcogenide compounds are calculated by the first-principles schemes of pseudopotential plane-wave based on spin-density functional theory, to study dynamic structural stability and electronic spin-splitting due to spin-orbit coupling...
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sg-ntu-dr.10356-1606602022-07-29T06:03:17Z Spin-orbit coupling and spin-polarized electronic structures of Janus vanadium-dichalcogenide monolayers: first-principles calculations Lv, Ming-Hao Li, Chang Ming Sun, Weifeng School of Electrical and Electronic Engineering Engineering::Electrical and electronic engineering Phonon Structure Electronic Structure Phonon and spintronic structures of monolayered Janus vanadium-dichalcogenide compounds are calculated by the first-principles schemes of pseudopotential plane-wave based on spin-density functional theory, to study dynamic structural stability and electronic spin-splitting due to spin-orbit coupling (SOC) and spin polarization. Geometry optimizations and phonon-dispersion spectra demonstrate that vanadium-dichalcogenide monolayers possess a high enough cohesive energy, while VSTe and VTe2 monolayers specially possess a relatively higher in-plane elastic coefficient and represent a dynamically stable structure without any virtual frequency of atomic vibration modes. Atomic population charges and electron density differences demonstrate that V-Te covalent bonds cause a high electrostatic potential gradient perpendicular to layer-plane internal VSTe and VSeTe monolayers. The spin polarization of vanadium 3d-orbital component causes a pronounced energetic spin-splitting of electronic-states near the Fermi level, leading to a semimetal band-structure and increasing optoelectronic band-gap. Rashba spin-splitting around G point in Brillouin zone can be specifically introduced into Janus VSeTe monolayer by strong chalcogen SOC together with a high intrinsic electric field (potential gradient) perpendicular to layer-plane. The vertical splitting of band-edge at K point can be enhanced by a stronger SOC of the chalcogen elements with larger atom numbers for constituting Janus V-dichalcogenide monolayers. The collinear spin-polarization causes the band-edge spin-splitting across Fermi level and leads to a ferrimagnetic order in layer-plane between V and chalcogen cations with higher α and β spin densities, respectively, which accounts for a large net spin as manifested more apparently in VSeTe monolayer. In a conclusion for Janus vanadium-dichalcogenide monolayers, the significant Rashba splitting with an enhanced K-point vertical splitting can be effectively introduced by a strong SOC in VSeTe monolayer, which simultaneously represents the largest net spin of 1.64 (ћ/2) per unit cell. The present study provides a normative scheme for first-principles electronic structure calculations of spintronic low-dimensional materials, and suggests a prospective extension of two-dimensional compound materials applied to spintronics. Published version This research was funded by National Natural Science Foundation of China (Grant No. 51337002). 2022-07-29T06:03:17Z 2022-07-29T06:03:17Z 2022 Journal Article Lv, M., Li, C. M. & Sun, W. (2022). Spin-orbit coupling and spin-polarized electronic structures of Janus vanadium-dichalcogenide monolayers: first-principles calculations. Nanomaterials, 12(3), 382-. https://dx.doi.org/10.3390/nano12030382 2079-4991 https://hdl.handle.net/10356/160660 10.3390/nano12030382 35159727 2-s2.0-85123342275 3 12 382 en Nanomaterials © 2022 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https:// creativecommons.org/licenses/by/ 4.0/). application/pdf |
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Engineering::Electrical and electronic engineering Phonon Structure Electronic Structure Lv, Ming-Hao Li, Chang Ming Sun, Weifeng Spin-orbit coupling and spin-polarized electronic structures of Janus vanadium-dichalcogenide monolayers: first-principles calculations |
| description |
Phonon and spintronic structures of monolayered Janus vanadium-dichalcogenide compounds are calculated by the first-principles schemes of pseudopotential plane-wave based on spin-density functional theory, to study dynamic structural stability and electronic spin-splitting due to spin-orbit coupling (SOC) and spin polarization. Geometry optimizations and phonon-dispersion spectra demonstrate that vanadium-dichalcogenide monolayers possess a high enough cohesive energy, while VSTe and VTe2 monolayers specially possess a relatively higher in-plane elastic coefficient and represent a dynamically stable structure without any virtual frequency of atomic vibration modes. Atomic population charges and electron density differences demonstrate that V-Te covalent bonds cause a high electrostatic potential gradient perpendicular to layer-plane internal VSTe and VSeTe monolayers. The spin polarization of vanadium 3d-orbital component causes a pronounced energetic spin-splitting of electronic-states near the Fermi level, leading to a semimetal band-structure and increasing optoelectronic band-gap. Rashba spin-splitting around G point in Brillouin zone can be specifically introduced into Janus VSeTe monolayer by strong chalcogen SOC together with a high intrinsic electric field (potential gradient) perpendicular to layer-plane. The vertical splitting of band-edge at K point can be enhanced by a stronger SOC of the chalcogen elements with larger atom numbers for constituting Janus V-dichalcogenide monolayers. The collinear spin-polarization causes the band-edge spin-splitting across Fermi level and leads to a ferrimagnetic order in layer-plane between V and chalcogen cations with higher α and β spin densities, respectively, which accounts for a large net spin as manifested more apparently in VSeTe monolayer. In a conclusion for Janus vanadium-dichalcogenide monolayers, the significant Rashba splitting with an enhanced K-point vertical splitting can be effectively introduced by a strong SOC in VSeTe monolayer, which simultaneously represents the largest net spin of 1.64 (ћ/2) per unit cell. The present study provides a normative scheme for first-principles electronic structure calculations of spintronic low-dimensional materials, and suggests a prospective extension of two-dimensional compound materials applied to spintronics. |
| author2 |
School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Lv, Ming-Hao Li, Chang Ming Sun, Weifeng |
| format |
Article |
| author |
Lv, Ming-Hao Li, Chang Ming Sun, Weifeng |
| author_sort |
Lv, Ming-Hao |
| title |
Spin-orbit coupling and spin-polarized electronic structures of Janus vanadium-dichalcogenide monolayers: first-principles calculations |
| title_short |
Spin-orbit coupling and spin-polarized electronic structures of Janus vanadium-dichalcogenide monolayers: first-principles calculations |
| title_full |
Spin-orbit coupling and spin-polarized electronic structures of Janus vanadium-dichalcogenide monolayers: first-principles calculations |
| title_fullStr |
Spin-orbit coupling and spin-polarized electronic structures of Janus vanadium-dichalcogenide monolayers: first-principles calculations |
| title_full_unstemmed |
Spin-orbit coupling and spin-polarized electronic structures of Janus vanadium-dichalcogenide monolayers: first-principles calculations |
| title_sort |
spin-orbit coupling and spin-polarized electronic structures of janus vanadium-dichalcogenide monolayers: first-principles calculations |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/160660 |
| _version_ |
1739837428594638848 |