铁弹性
凝聚态物理
自旋电子学
点反射
四方晶系
铁磁性
多铁性
简并能级
材料科学
对称(几何)
单层
自旋(空气动力学)
各向异性
领域
相变
对称性破坏
物理
Crystal(编程语言)
电致伸缩
电导
单晶
沙漏
应变工程
三角晶系
作者
Yuqiang Huang,Chenqiang Hua,Runzhang Xu,Junwei Liu,Yi Zheng,Yunhao Lu
摘要
The realm of spintronics has witnessed a profound surge in fascination towards altermagnetism, fueled by groundbreaking predictions and a myriad of promising applications. Here, we propose a novel multiferroic mechanism between ferroelasticity and altermagnetism based on symmetry analysis. Through first-principles calculations, we predict monolayer Janus tetragonal V_{2}OS and series of related materials as promising material candidates, where ferroelastic strain breaks the intrinsic symmetry of altermagnetism, transforming it into a compensated ferrimagnetic state and enabling the manipulation of spin-polarized states through ferroelastic switching. The magnetic order of monolayer V_{2}OS could survive above room temperature with manageable ferroelastic switching energy, indicating immense potential for practical applications. Furthermore, by calculating the in-plane spin conductance and simulating magnetic tunnel junctions, we demonstrate that V_{2}OS can discriminate spin states along both in-plane and out-of-plane directions. These findings open up novel avenues for two-dimensional altermagnetism-based spintronics, particularly in the realm of high-density, low-power consumption, and non-volatile information storage devices.
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