Topological monopole's gauge field‐induced anomalous Hall effect in artificial honeycomb lattice

IF 2.6 Q2 MULTIDISCIPLINARY SCIENCES Natural sciences (Weinheim, Germany) Pub Date : 2022-07-12 DOI:10.1002/ntls.20210083
Jiasen Guo, V. Dugaev, A. Ernst, G. Yumnam, Pousali Ghosh, D. Singh
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引用次数: 1

Abstract

Vortex magnetic structure in artificial honeycomb lattice provides a unique platform to explore emergent properties due to the additional Berry phase curvature imparted by chiral magnetization to circulating electrons via direct interaction. We argue that while the perpendicularly-aligned magnetic component leads to the quantized flux of monopole at the center of the Berry sphere, the in-plane vortex circulation of magnetization gives rise to unexpected non-trivial topological Berry phase due to the gauge field transformation. The unprecedented effect signifies the importance of vector potential in multiply-connected geometrical systems. Experimental confirmations to proposed hypotheses are obtained from Hall resistance measurements on permalloy honeycomb lattice. Investigation of the topological gauge transformation due to the in-plane chirality reveals anomalous quasi-oscillatory behavior in Hall resistance $R_{xy}$ as function of perpendicular field. The oscillatory nature of $R_{xy}$ is owed to the fluctuation in equilibrium current as a function of Fermi wave-vector $k_F$, envisaged under the proposed new formulation in this article. Our synergistic approach suggests that artificially tunable nanostructured material provides new vista to the exploration of topological phenomena of strong fundamental importance.

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人工蜂窝晶格中拓扑单极子规范场诱导的反常霍尔效应
人工蜂窝晶格中的涡旋磁结构提供了一个独特的平台来探索由于手性磁化通过直接相互作用赋予循环电子额外的贝里相曲率而产生的涌现特性。我们认为,虽然垂直排列的磁分量导致Berry球中心单极子的量子化通量,但由于规范场变换,磁化的平面内涡旋循环会产生意想不到的非平凡拓扑Berry相。这一前所未有的效应表明了向量势在多连通几何系统中的重要性。通过对坡莫合金蜂窝晶格的霍尔电阻测量,实验证实了上述假设。研究了由于面内手性引起的拓扑规范变换,揭示了霍尔电阻R_{xy}$随垂直场的变化具有反常的准振荡行为。R_{xy}$的振荡性质是由于平衡电流作为费米波矢量k_F$的函数的波动,这是在本文提出的新公式中设想的。我们的协同方法表明,人工可调谐纳米结构材料为探索具有重要基础意义的拓扑现象提供了新的前景。
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