Spin-reorientation driven emergent phases and unconventional magnetotransport in quasi-2D vdW ferromagnet Fe4GeTe2

IF 9.1 2区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

npj 2D Materials and Applications Pub Date : 2024-04-05 DOI:10.1038/s41699-024-00463-y

Riju Pal, Buddhadeb Pal, Suchanda Mondal, Rajesh O. Sharma, Tanmoy Das, Prabhat Mandal, Atindra Nath Pal

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Abstract

Non-trivial spin textures driven by strong exchange interaction, magneto-crystalline anisotropy, and electron correlation in a low-dimensional magnetic material often lead to unusual electronic transitions. Through a combination of transport experiments in exfoliated nanoflakes down to 16 layers and first principle calculations, we unravel emergent electronic phases in quasi-2D van der Waals ferromagnet, Fe4GeTe2, possessing ferromagnetic TC ~ 270 K, along with a spin-reorientation transition (TSR ~ 120 K) with the change of magnetic easy axis. Two electronic transitions are identified. The first transition near TSR exhibits a sharp fall in resistivity, followed by a sign change in the ordinary Hall coefficient (R0), together with, maximum negative magnetoresistance (MR) and anomalous Hall conductivity. Another unusual electronic transition, hitherto unknown, is observed near ~ 40–50 K (TQ), where R0 again changes sign and below which, the resistivity shows a quadratic temperature dependence, and MR becomes positive. An analysis of the experimental data further uncovers the role of competing inelastic scattering processes in anomalous magnetotransport behavior. The density-functional theory based first-principle calculations unveil two possible magnetic phases, followed by a low-energy model Hamiltonian which captures the essence of these phases as well as explains the observed magnetotransport behavior. Thus, we demonstrate an interplay between magnetism and band topology and its consequence on electron transport in Fe4GeTe2, important for spintronic applications.

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准二维 vdW 铁磁体 Fe4GeTe2 中的自旋定向驱动新兴相和非常规磁传输

在低维磁性材料中，由强交换相互作用、磁晶各向异性和电子相关性驱动的非三维自旋纹理往往会导致不寻常的电子转变。通过在剥离至 16 层的纳米片中进行输运实验和第一原理计算相结合，我们揭示了准二维范德华铁磁体 Fe4GeTe2 中出现的电子相，它具有铁磁性 TC ~ 270 K，同时随着磁易轴的改变而出现自旋定向转变（TSR ~ 120 K）。确定了两个电子转变。在 TSR 附近的第一个转变表现为电阻率急剧下降，随后普通霍尔系数（R0）发生符号变化，同时出现最大负磁电阻（MR）和反常霍尔电导率。在 ~ 40-50 K (TQ) 附近观察到另一个迄今未知的不寻常电子转变，此时 R0 的符号再次发生改变，在此温度以下，电阻率显示出二次温度依赖性，MR 变为正值。对实验数据的分析进一步揭示了竞争性非弹性散射过程在异常磁传输行为中的作用。基于密度泛函理论的第一原理计算揭示了两种可能的磁性阶段，随后的低能模型哈密顿能捕捉到这些阶段的本质，并解释了观察到的磁传输行为。因此，我们证明了磁性和带拓扑之间的相互作用及其对 Fe4GeTe2 中电子传输的影响，这对自旋电子应用非常重要。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

npj 2D Materials and Applications Engineering-Mechanics of Materials

CiteScore

14.50

自引率

2.10%

发文量

审稿时长

15 weeks

期刊介绍： npj 2D Materials and Applications publishes papers on the fundamental behavior, synthesis, properties and applications of existing and emerging 2D materials. By selecting papers with the potential for impact, the journal aims to facilitate the transfer of the research of 2D materials into wide-ranging applications.