Observation of Colossal Topological Hall Effect in Noncoplanar Ferromagnet Cr₅Te₆ Thin Films.

Chen, Yequan; Zhu, Yingmei; Lin, Renju; Niu, Wei; Liu, Ruxin; Zhuang, Wenzhuo; Zhang, Xu; Liang, Jinghua; Sun, Wenxuan; Chen, Zhongqiang; Hu, Yongsheng; Song, Fengqi; Zhou, Jian; Wu, Di; Ge, Binghui; Yang, Hongxin; Zhang, Rong; Wang, Xuefeng

The topological Hall effect (THE) is critical to the exploration of the spin chirality generated by the real‐space Berry curvature, which has attracted worldwide attention for its prospective applications in spintronic devices. However, the prominent THE remains elusive at room temperature, which severely restricts the practical integration of chiral spin textures. Here, a colossal intrinsic THE is showed up to ≈1.6 µΩ cm in large‐area ferromagnet Cr5Te6 thin films epitaxially grown by pulsed laser deposition. Such a THE can be maintained until 270 K, which is attributed to the field‐stimulated noncoplanar spin textures induced by the interaction of the in‐plane ferromagnet and antiferromagnet infrastructures. The first‐principles calculations further verify the considerable Dzyaloshinskii‐Moriya interaction in Cr5Te6. This work not only paves the way for robust chiral spin textures near room temperature in large‐area low‐dimensional ferromagnetic films for practical applications, but also facilitates the development of high‐density and dissipationless spintronic devices.

HALL effect; THIN films; FERROMAGNETIC materials; PULSED laser deposition; CHIRALITY of nuclear particles

Advanced Functional Materials, 2023, Vol 33, Issue 33, p1

1616-301X

Academic Journal

10.1002/adfm.202302984