Direct Evidence of Anomalous Peierls Transition-Induced Charge Density Wave Order at Room Temperature in Metallic NaRu2O4.

IF 2.9 4区工程技术 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY Microscopy and Microanalysis Pub Date : 2025-01-13 DOI:10.1093/mam/ozae129

Anna Scheid, Isha, Arvind Kumar Yogi, Masahiko Isobe, Birgit Bußmann, Tobias Heil, Peter A van Aken

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Abstract

In the field of quantum materials, understanding anomalous behavior under charge degrees of freedom through bond formation is of fundamental importance, with two key concepts: Dimerization and charge order at different cation sites. The coexistence of both dimerization and charge ordering is unusually found in NaRu2O4, even in its metallic state at room temperature. Our work unveils the origin of the interplay of these effects within metallic single-crystalline NaRu2O4. Employing advanced transmission electron microscopy techniques, we probe the lattice order of NaRu2O4 as a function of temperature and provide direct microscopic evidence of a Peierls-type transition. This transition is accompanied by a pronounced dimerization of the ruthenium chains, resulting in a distinctive twofold superstructure along the b axis below the critical transition temperature of ∼535 K, coinciding with a charge order. In situ heating experiments confirm the reversibility of this first-order phase transition, and periodic lattice displacement maps depict atomic-scale displacements linked to dimerization.

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金属NaRu2O4在室温下异常peerls跃迁诱导电荷密度波序的直接证据。

在量子材料领域，通过键的形成来理解电荷自由度下的异常行为是至关重要的，其中有两个关键概念：二聚化和不同阳离子位置的电荷顺序。在常温下的金属态NaRu2O4中，二聚化现象和电荷有序现象同时存在。我们的工作揭示了金属单晶NaRu2O4中这些效应相互作用的起源。利用先进的透射电子显微镜技术，我们探测了NaRu2O4的晶格顺序随温度的变化，并提供了peerls型转变的直接显微证据。这种转变伴随着明显的钌链二聚化，导致在临界转变温度~ 535 K以下沿b轴形成独特的双重上层结构，与电荷顺序一致。原位加热实验证实了这种一阶相变的可逆性，周期性晶格位移图描述了与二聚化有关的原子尺度位移。

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来源期刊

Microscopy and Microanalysis 工程技术-材料科学：综合

CiteScore

1.10

自引率

10.70%

发文量

1391

审稿时长

6 months

期刊介绍： Microscopy and Microanalysis publishes original research papers in the fields of microscopy, imaging, and compositional analysis. This distinguished international forum is intended for microscopists in both biology and materials science. The journal provides significant articles that describe new and existing techniques and instrumentation, as well as the applications of these to the imaging and analysis of microstructure. Microscopy and Microanalysis also includes review articles, letters to the editor, and book reviews.