2020
DOI: 10.21203/rs.3.rs-114140/v1
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Spin-polarized Dirac cone, flat band and saddle point in kagome magnet YMn6Sn6

Abstract: Kagome-lattice of 3d-transition metals hosting Weyl/Dirac fermions and topological flat bands exhibit non-trivial topological characters and novel quantum phases, such as anomalous Hall effect and fractional quantum Hall effect. With consideration of spin-orbit coupling and electron correlation, several instabilities could be induced. The complete characters of the electronic structure of kagome lattice, i.e. the saddle point, Dirac-cone, and flat band, around the Fermi energy (EF) remain elusive in magnetic kag… Show more

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Cited by 3 publications
(4 citation statements)
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“…This interesting observation supports the critical role of magnetic coupling in the MDF structure. On the other hand, the THE and electronic structure in YMn 6 Sn 6 which has no 4f moments, deserve further elaboration [23][24][25]. Our work highlights the material system which not only largely extends the family of quantum kagome magnets but also intrinsically contains a quantum knob for Chern phase engineering.…”
mentioning
confidence: 74%
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“…This interesting observation supports the critical role of magnetic coupling in the MDF structure. On the other hand, the THE and electronic structure in YMn 6 Sn 6 which has no 4f moments, deserve further elaboration [23][24][25]. Our work highlights the material system which not only largely extends the family of quantum kagome magnets but also intrinsically contains a quantum knob for Chern phase engineering.…”
mentioning
confidence: 74%
“…When R is Er and Tm, the Mn and Er=Tm sublattices are independently ordered in an AFM manner because the strength of the magnetic coupling is weak [17,18]. As there is no 4f moment in LuMn 6 Sn 6 , its magnetic structure was reported to be a flat spiral AFM [22], similar to that in YMn 6 Sn 6 [23][24][25].…”
mentioning
confidence: 98%
“…A typical kagome-lattice electronic band produced by the tight-binding model is characterized by a Dirac dispersion at the Brillouin zone (BZ) corner, a saddle point at the zone boundary, and a flat band through the BZ. The versatile quantum phenomena can be realized by tuning any of them close to the Fermi energy (E F ), such as Dirac/Weyl fermions [1][2][3][4][5][6][7][8][9][10][11][12][13], ferromagnetism [14][15][16], negative flat band magnetism [17], and topological Chern magnet [18]. Recently, superconductivity is discovered in a new family of layered kagome metals AV 3 Sb 5 (A= K, Rb, and Cs) (T c ∼0.9-2.5 K) [19][20][21][22][23], which host a Z 2 topological invariant and non-trivial topological Dirac surface states near E F [20].…”
mentioning
confidence: 99%
“…The CDW-related 2×2 lattice reconstruction is expected to generate electronic structure reconstruction, as illustrated in Fig.1d. However, no signature of such electronic reconstruction has been detected in the previous ARPES measurements[2,[37][38][39][40][41][42][43][44]. We have observed clear evidence of electronic structure reconstruction induced by the 2×2 CDW transition in KV 3 Sb 5 both in the measured Fermi surface and the band structure.Fig.…”
mentioning
confidence: 53%