WCl3 单层:外加电场下电子和磁性能的第一原理预测

IF 2.2 4区 工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC
Md. Azaharuddin Ahmed, A. L. Safi
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引用次数: 0

摘要

本研究的重点是预测单层 WCl3 在外部电场作用下的电子和磁性行为。与 CrI3 不同的是,WCl3 单层显示出一种偏好的反铁磁性(AFM)基态,具有面内易轴。这种 AFM 状态在外加电场的整个频谱(0-1 V/Å)内都保持一致。据预测,WCl3 单层的间接电子带隙约为 2.16 eV。通过分析,我们发现价带最大值和导带最小值的主要来源分别是 W 元素的 \({d}_{x}^{2}-{y}^{2}} 轨道(占 52% 的贡献)和 \({d}_{z}^{2}}\) 轨道(占 97% 的贡献)。与带隙有关的大多数电子跃迁都是由这些特定轨道引起的。此外,施加外部电场可将带隙调整为零,在电场强度为 E = 0.9 V/Å 时促使从半导体转变为金属。利用平均场理论,我们估计原子力显微镜系统的尼尔温度(TN)约为 356 K,明显高于室温。此外,电场的应用显示了进一步提高 Neel 温度的潜力,这对高温自旋电子器件的功能至关重要。我们的全面研究还深入探讨了 WCl3 单层的磁各向异性。对磁各向异性能(MAE)的分析表明,与CrI3单层相反,过渡金属W对该体系的MAE有显著的贡献,预测值为-\(3.44\text{meV}/\text{W}\)。磁易轴沿 \(x\) 方向(面内)排列。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

WCl3 monolayer: a first principles prediction of electronic and magnetic properties under an external electric field

WCl3 monolayer: a first principles prediction of electronic and magnetic properties under an external electric field

WCl3 monolayer: a first principles prediction of electronic and magnetic properties under an external electric field

This current study focuses on predicting the electronic and magnetic behaviors of WCl3 monolayer when subjected to an external electric field. Unlike CrI3, the WCl3 monolayer displays a preference for an antiferromagnetic (AFM) ground state with an in-plane easy axis. This AFM state remains consistent across the entire spectrum (0–1 V/Å) of the external electric field. The indirect electronic band gap of the WCl3 monolayer is predicted to be about 2.16 eV. Through our analysis, we’ve identified that the dominance of the valence band maximum and the conduction band minimum stems mainly from the \({d}_{{x}^{2}-{y}^{2}}\) orbital (52% contribution) and the \({d}_{{z}^{2}}\) orbital (97% contribution) respectively, attributed to the W element. The majority of electronic transitions related to the band gap arise due to these specific orbitals. Furthermore, the application of an external electric field can adjust the band gap to zero, prompting a transition from semiconductor to metal at an electric field intensity of E = 0.9 V/Å. Using mean field theory, we estimate the Neel temperature (TN) of the AFM system to be approximately 356 K, a notably high value surpassing room temperature. Moreover, the application of an electric field demonstrates the potential to further elevate the Neel temperature, crucial for the functionality of high-temperature spintronic devices. Our comprehensive examination also delves into the magnetic anisotropy of the WCl3 monolayer. The analysis of magnetic anisotropy energy (MAE) indicates that, contrary to the CrI3 monolayer, the transition metal W significantly contributes to the system’s MAE, which is predicted to be − \(3.44\text{ meV}/\text{W}\). The magnetic easy axis aligns along the \(x\) direction (in-plane).

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来源期刊
Journal of Computational Electronics
Journal of Computational Electronics ENGINEERING, ELECTRICAL & ELECTRONIC-PHYSICS, APPLIED
CiteScore
4.50
自引率
4.80%
发文量
142
审稿时长
>12 weeks
期刊介绍: he Journal of Computational Electronics brings together research on all aspects of modeling and simulation of modern electronics. This includes optical, electronic, mechanical, and quantum mechanical aspects, as well as research on the underlying mathematical algorithms and computational details. The related areas of energy conversion/storage and of molecular and biological systems, in which the thrust is on the charge transport, electronic, mechanical, and optical properties, are also covered. In particular, we encourage manuscripts dealing with device simulation; with optical and optoelectronic systems and photonics; with energy storage (e.g. batteries, fuel cells) and harvesting (e.g. photovoltaic), with simulation of circuits, VLSI layout, logic and architecture (based on, for example, CMOS devices, quantum-cellular automata, QBITs, or single-electron transistors); with electromagnetic simulations (such as microwave electronics and components); or with molecular and biological systems. However, in all these cases, the submitted manuscripts should explicitly address the electronic properties of the relevant systems, materials, or devices and/or present novel contributions to the physical models, computational strategies, or numerical algorithms.
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