Salvato in:
Dettagli Bibliografici
Autori principali: Lou, Rui, Zhou, Liqin, Song, Wenhua, Fedorov, Alexander, Tu, Zhijun, Jiang, Bei, Wang, Qi, Li, Man, Liu, Zhonghao, Chen, Xuezhi, Rader, Oliver, Büchner, Bernd, Sun, Yujie, Weng, Hongming, Lei, Hechang, Wang, Shancai
Natura: Preprint
Pubblicazione: 2023
Soggetti:
Accesso online:https://arxiv.org/abs/2309.06399
Tags: Aggiungi Tag
Nessun Tag, puoi essere il primo ad aggiungerne!!
_version_ 1866917836628164608
author Lou, Rui
Zhou, Liqin
Song, Wenhua
Fedorov, Alexander
Tu, Zhijun
Jiang, Bei
Wang, Qi
Li, Man
Liu, Zhonghao
Chen, Xuezhi
Rader, Oliver
Büchner, Bernd
Sun, Yujie
Weng, Hongming
Lei, Hechang
Wang, Shancai
author_facet Lou, Rui
Zhou, Liqin
Song, Wenhua
Fedorov, Alexander
Tu, Zhijun
Jiang, Bei
Wang, Qi
Li, Man
Liu, Zhonghao
Chen, Xuezhi
Rader, Oliver
Büchner, Bernd
Sun, Yujie
Weng, Hongming
Lei, Hechang
Wang, Shancai
contents Kagome magnets provide a fascinating platform for the realization of correlated topological quantum phases under various magnetic ground states. However, the effect of the magnetic spin configurations on the characteristic electronic structure of the kagome lattice layer remains elusive. Here, utilizing angle-resolved photoemission spectroscopy and density functional theory calculations, we report the spectroscopic evidence for the spin-reorientation effect of a kagome ferromagnet Fe$_3$Ge, which is composed solely of kagome planes. As the Fe moments cant from the $c$ axis into the $ab$ plane upon cooling, the two kinds of kagome-derived Dirac fermions respond quite differently. The one with less-dispersive bands ($k_z$ $\sim$ 0) containing the $3d_{z^2}$ orbitals evolves from gapped into nearly gapless, while the other with linear dispersions ($k_z$ $\sim$ $π$) embracing the $3d_{xz}$/$3d_{yz}$ components remains intact, suggesting that the effect of spin reorientation on the Dirac fermions has an orbital selectivity. Moreover, we demonstrate that there is no signature of charge order formation in Fe$_3$Ge, contrasting with its sibling compound FeGe, a newly established charge-density-wave kagome magnet.
format Preprint
id arxiv_https___arxiv_org_abs_2309_06399
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Orbital-selective effect of spin reorientation on the Dirac fermions in a non-charge-ordered kagome ferromagnet Fe$_3$Ge
Lou, Rui
Zhou, Liqin
Song, Wenhua
Fedorov, Alexander
Tu, Zhijun
Jiang, Bei
Wang, Qi
Li, Man
Liu, Zhonghao
Chen, Xuezhi
Rader, Oliver
Büchner, Bernd
Sun, Yujie
Weng, Hongming
Lei, Hechang
Wang, Shancai
Strongly Correlated Electrons
Materials Science
Kagome magnets provide a fascinating platform for the realization of correlated topological quantum phases under various magnetic ground states. However, the effect of the magnetic spin configurations on the characteristic electronic structure of the kagome lattice layer remains elusive. Here, utilizing angle-resolved photoemission spectroscopy and density functional theory calculations, we report the spectroscopic evidence for the spin-reorientation effect of a kagome ferromagnet Fe$_3$Ge, which is composed solely of kagome planes. As the Fe moments cant from the $c$ axis into the $ab$ plane upon cooling, the two kinds of kagome-derived Dirac fermions respond quite differently. The one with less-dispersive bands ($k_z$ $\sim$ 0) containing the $3d_{z^2}$ orbitals evolves from gapped into nearly gapless, while the other with linear dispersions ($k_z$ $\sim$ $π$) embracing the $3d_{xz}$/$3d_{yz}$ components remains intact, suggesting that the effect of spin reorientation on the Dirac fermions has an orbital selectivity. Moreover, we demonstrate that there is no signature of charge order formation in Fe$_3$Ge, contrasting with its sibling compound FeGe, a newly established charge-density-wave kagome magnet.
title Orbital-selective effect of spin reorientation on the Dirac fermions in a non-charge-ordered kagome ferromagnet Fe$_3$Ge
topic Strongly Correlated Electrons
Materials Science
url https://arxiv.org/abs/2309.06399