Topological nodal-line semimetals in ferromagnetic rare-earth-metal monohalides

Nie, Simin; Weng, Hongming; Prinz, Fritz B.

doi:10.1103/physrevb.99.035125

Cited by 70 publications

(48 citation statements)

References 77 publications

(66 reference statements)

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“…S2 and S3 [22]. This is consistent with the results reported for bulk LaCl recently [25]. Here, the magnetic anisotropic energy (MAE) (∼ 0.15 meV/La) is comparable to that in monolayer CrI 3 [26,27], but much larger than that in pure magnetic metals [28].…”

Section: Magnetization Requirementsupporting

confidence: 91%

Intrinsic Quantum Anomalous Hall Effect with In-Plane Magnetization: Searching Rule and Material Prediction

et al. 2018

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So far, most theoretically predicted and experimentally confirmed quantum anomalous Hall effect (QAHE) are limited in two-dimensional (2D) materials with out-of-plane magnetization. In this Letter, starting from 2D nodal-line semimetal, a general rule for searching QAHE with in-plane magnetization is mapped out. Due to the spin-orbital-coupling, we found that the magnetization will prefer an in-plane orientation if the orbital of degenerate nodal-line states at Fermi-level have the same absolute value of magnetic quantum number. Moreover, depending on the broken or conserved mirror symmetry, either QAHE or 2D semimetal can be realized. Based on first principles calculations, we further predict a real material of monolayer LaCl to be an intrinsic QAHE with in-plane magnetization. By tuning the directions of in-plane magnetization, the QAHE in LaCl demonstrates a threefold rotational symmetry with Chern number of either +1 or −1, and the transition point is characterized by a 2D semimetal phase. All these features are quantitatively reproduced by tight-binding model calculations, revealing the underlying physics clearly. Our results greatly extend the scope for material classes of QAHE, and hence stimulate immediate experimental interests.

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Section: Magnetization Requirementsupporting

confidence: 91%

Intrinsic Quantum Anomalous Hall Effect with In-Plane Magnetization: Searching Rule and Material Prediction

et al. 2018

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“…We recall that Weyl points are massless Dirac fermions that appear in pairs of opposite parity, protected by the lattice translational symmetry. Additional mirror symmetry can stabilize Weyl points in a twodimensional system 61 , as it has been reported for GdAg 2 , where band degeneracies of this type appear close to the Fermi level not as discrete points, but forming a line, so-called Weyl nodal line 60 . In GdAg 2 and ErCu 2 the upward-dispersing spin-majority d xz band and the downward-dispersing spin-minority C mutually cross near the Fermi level, defining topologically protected Weyl nodal lines 5,60 .…”

Section: Band Structurementioning

confidence: 63%

Influence of 4f filling on electronic and magnetic properties of rare earth-Au surface compounds

et al. 2020

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“…In 2019, Nie et al [64] predicted the spinful nodal lines in 3D layered materials LaX (X=Cl, Br), which are constructed by stacking 2D Weyl materials. Generally, Weyl nodes can exist in 2D materials protected by crystal symmetry, for example, one pair of Weyl nodes protected by mirror symmetry M y .…”

Section: Lacl (Labr)mentioning

confidence: 99%

The study of magnetic topological semimetals by first principles calculations

Zou

2019

npj Comput Mater

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Magnetic topological semimetals (TSMs) are topological quantum materials with broken timereversal symmetry (TRS) and isolated nodal points or lines near the Fermi level. Their topological properties would typically reveal from the bulk-edge correspondence principle as nontrivial surface states such as Fermi arcs or drumhead states, etc. Depending on the degeneracies and distribution of the nodes in the crystal momentum space, TSMs are usually classified into Weyl semimetals (WSMs), Dirac semimetals (DSMs), nodal-line semimetals (NLSMs), triple-point semimetals (TPSMs), etc.In this review article, we present the recent advances of magnetic TSMs from a computational perspective. We first review the early predicted magnetic WSMs such as pyrochlore iridates and HgCr2Se4, as well as the recently proposed Heusler, Kagome layers, and honeycomb lattice WSMs.Then we discuss the recent developments of magnetic DSMs, especially CuMnAs in Type-III and EuCd2As2 in Type-IV magnetic space groups (MSGs). Then we introduce some magnetic NLSMs that are robust against spin-orbit coupling (SOC), namely Fe3GeTe2 and LaCl (LaBr). Finally, we discuss the prospects of magnetic TSMs and the interesting directions for future research. *

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Topological nodal-line semimetals in ferromagnetic rare-earth-metal monohalides

Cited by 70 publications

References 77 publications

Intrinsic Quantum Anomalous Hall Effect with In-Plane Magnetization: Searching Rule and Material Prediction

Intrinsic Quantum Anomalous Hall Effect with In-Plane Magnetization: Searching Rule and Material Prediction

Influence of 4f filling on electronic and magnetic properties of rare earth-Au surface compounds

The study of magnetic topological semimetals by first principles calculations

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