磁性
物理
凝聚态物理
Berry连接和曲率
塞曼效应
自旋(空气动力学)
磁场
几何相位
量子力学
热力学
作者
Jia‐Xin Yin,Songtian S. Zhang,Guoqing Chang,Qi Wang,Stepan S. Tsirkin,Zurab Guguchia,Biao Lian,Huibin Zhou,Kun Jiang,Ilya Belopolski,Nana Shumiya,Daniel Multer,Maksim Litskevich,Tyler A. Cochran,Hsin Lin,Ziqiang Wang,Titus Neupert,Shuang Jia,Hechang Lei,M. Zahid Hasan
出处
期刊:Nature Physics
[Springer Nature]
日期:2019-02-18
卷期号:15 (5): 443-448
被引量:356
标识
DOI:10.1038/s41567-019-0426-7
摘要
It has long been speculated that electronic flat band systems can be a fertile ground for hosting novel emergent phenomena including unconventional magnetism and superconductivity. Although flat bands are known to exist in a few systems such as heavy fermion materials and twisted bilayer graphene, their microscopic roles and underlying mechanisms in generating emergent behavior remain elusive. Here we use scanning tunneling microscopy to elucidate the atomically resolved electronic states and their magnetic response in the kagome magnet Co3Sn2S2. We observe a pronounced peak at the Fermi level, which is identified to arise from the kinetically frustrated kagome flat band. Increasing magnetic field up to +-8T, this state exhibits an anomalous magnetization-polarized Zeeman shift, dominated by an orbital moment in opposite to the field direction. Such negative magnetism can be understood as spin-orbit coupling induced quantum phase effects tied to non-trivial flat band systems. We image the flat band peak, resolve the associated negative magnetism, and provide its connection to the Berry curvature field, showing that Co3Sn2S2 is a rare example of kagome magnet where the low energy physics can be dominated by the spin-orbit coupled flat band. Our methodology of probing band-resolved ordering phenomena such as spin-orbit magnetism can also be applied in future experiments to elucidate other exotic phenomena including flat band superconductivity and anomalous quantum transport.
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