Switching intrinsic magnetic skyrmions with controllable magnetic anisotropy in van der Waals multiferroic heterostructures

arXiv - PHYS - Materials Science Pub Date : 2024-03-09 DOI:arxiv-2403.05747

Ze-quan Wang, Feng Xue, Liang Qiu, Zhe Wang, Ruqian Wu, Yusheng Hou

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Abstract

Magnetic skyrmions, topologically nontrivial whirling spin textures at nanometer scales, have emerged as potential information carriers for spintronic devices. The ability to efficiently create and erase magnetic skyrmions is vital yet challenging for such applications. Based on first-principles studies, we find that switching between intrinsic magnetic skyrmion and high-temperature ferromagnetic states can be achieved in two-dimensional van der Waals (vdW) multiferroic heterostructure CrSeI/In2Te3 by reversing the ferroelectric polarization of In2Te3. The core mechanism of this switching is traced to the controllable magnetic anisotropy of CrSeI influenced by the ferroelectric polarization of In2Te3. We propose a useful descriptor linking the presence of magnetic skyrmions to magnetic parameters, and validate this connection through studies of a variety of similar vdW multiferroic heterostructures. Our work demonstrates that manipulating magnetic skyrmions via tunable magnetic anisotropies in vdW multiferroic heterostructures represents a highly promising and energy-efficient strategy for future development of spintronics.

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范德瓦尔斯多铁氧体异质结构中具有可控磁各向异性的开关式本征磁天线

磁天线是纳米尺度上拓扑学上的非三维旋转自旋纹理，已成为自旋电子器件的潜在信息载体。高效地创建和擦除磁天线的能力对于此类应用至关重要，但也极具挑战性。基于第一性原理研究，我们发现在二维范德瓦耳斯（vdW）多铁素体异质结构 CrSeI/In2Te3 中，通过反转 In2Te3 的铁电极化，可以实现本征磁天线和高温铁磁态之间的切换。这种切换的核心机制可追溯到受 In2Te3 铁电极化影响的 CrSeI 的可控磁各向异性。我们提出了一种有用的描述方法，将磁性天线的存在与磁性参数联系起来，并通过对各种类似的 vdW 多铁素体异质结构的研究验证了这种联系。我们的研究证明，在 vdW 多铁氧体异质结构中通过可调磁性各向异性来操纵磁天线，是未来开发自旋电子学的一种极具前景和能效的策略。

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arXiv - PHYS - Materials Science

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