Multimodal Approach Reveals the Symmetry-Breaking Pathway to the Broken Helix in EuIn2As2

IF 11.6 1区 物理与天体物理 Q1 PHYSICS, MULTIDISCIPLINARY
E. Donoway, T. V. Trevisan, A. Liebman-Peláez, R. P. Day, K. Yamakawa, Y. Sun, J. R. Soh, D. Prabhakaran, A. T. Boothroyd, R. M. Fernandes, J. G. Analytis, J. E. Moore, J. Orenstein, V. Sunko
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Abstract

Understanding and manipulating emergent phases, which are themes at the forefront of quantum-materials research, rely on identifying their underlying symmetries. This general principle has been particularly prominent in materials with coupled electronic and magnetic degrees of freedom, in which magnetic order influences the electronic band structure and can lead to exotic topological effects. However, identifying symmetry of a magnetically ordered phase can pose a challenge, particularly in the presence of small domains. Here we introduce a multimodal approach for determining magnetic structures, which combines symmetry-sensitive optical probes, scattering, and group-theoretical analysis. We apply it to EuIn2As2, a material that has received attention as a candidate axion insulator. While first-principles calculations predict this state on the assumption of a simple collinear antiferromagnetic structure, subsequent neutron-scattering measurements reveal a much more intricate magnetic ground state characterized by two coexisting magnetic wave vectors reached by successive thermal phase transitions. The proposed high- and low-temperature phases are a spin helix and a state with interpenetrating helical and Néel antiferromagnetic order termed a “broken helix,” respectively. Employing a multimodal approach, we identify the magnetic structure associated with these two phases of EuIn2As2. We find that the higher-temperature phase is characterized by a variation of the magnetic moment amplitude from layer to layer, with the moment vanishing entirely in every third Eu layer. The lower-temperature structure is similar to the broken helix, with one important difference: Because of local strain, the relative orientation of the magnetic structure and the lattice is not fixed. Consequently, the symmetry required to protect the axion phase is not generically protected in EuIn2As2, but we show that it can be restored if the magnetic structure is tuned with uniaxial strain. Finally, we present a spin Hamiltonian that identifies the spin interactions that account for the complex magnetic order in EuIn2As2. Our work highlights the importance of a multimodal approach in determining the symmetry of complex order parameters.

Abstract Image

多模态方法揭示 EuIn2As2 中断裂螺旋的对称性破坏途径
理解和操纵新兴相是量子材料研究的前沿主题,而理解和操纵新兴相则有赖于确定其基本对称性。这一一般原理在具有耦合电子自由度和磁性自由度的材料中尤为突出,在这些材料中,磁有序会影响电子带结构,并可能导致奇异的拓扑效应。然而,识别磁有序相的对称性是一项挑战,尤其是在存在小磁畴的情况下。在此,我们介绍一种确定磁结构的多模式方法,它结合了对称性敏感光学探针、散射和群论分析。我们将其应用于 EuIn2As2,这是一种作为候选轴心绝缘体而备受关注的材料。虽然第一原理计算是基于简单的对偶反铁磁结构假设来预测这种状态的,但随后的中子散射测量却揭示了一种更为复杂的磁基态,其特点是通过连续的热相变达到两个共存的磁波矢量。所提出的高温相和低温相分别是一种自旋螺旋态和一种具有相互渗透的螺旋阶和内尔反铁磁阶的态,称为 "破碎螺旋"。利用多模态方法,我们确定了与 EuIn2As2 这两个相相关的磁结构。我们发现,高温相的特点是磁矩振幅在各层之间发生变化,每隔三层 Eu 层磁矩就会完全消失。低温结构与断裂螺旋相似,但有一个重要区别:由于存在局部应变,磁结构和晶格的相对方向并不固定。因此,保护轴心相所需的对称性在 EuIn2As2 中一般不会受到保护,但我们的研究表明,如果用单轴应变调整磁结构,对称性是可以恢复的。最后,我们提出了一个自旋哈密顿,该哈密顿确定了导致 EuIn2As2 中复杂磁序的自旋相互作用。我们的工作凸显了多模式方法在确定复杂阶次参数对称性方面的重要性。
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来源期刊
Physical Review X
Physical Review X PHYSICS, MULTIDISCIPLINARY-
CiteScore
24.60
自引率
1.60%
发文量
197
审稿时长
3 months
期刊介绍: Physical Review X (PRX) stands as an exclusively online, fully open-access journal, emphasizing innovation, quality, and enduring impact in the scientific content it disseminates. Devoted to showcasing a curated selection of papers from pure, applied, and interdisciplinary physics, PRX aims to feature work with the potential to shape current and future research while leaving a lasting and profound impact in their respective fields. Encompassing the entire spectrum of physics subject areas, PRX places a special focus on groundbreaking interdisciplinary research with broad-reaching influence.
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