Spin-valley locking and bulk quantum Hall effect in a noncentrosymmetric Dirac semimetal BaMnSb2

Liu, Jinyu; Yu, Jiabin; Ning, Jinliang; Yi, Hemian; Miao, Leixin; Min, Lujin; Zhao, Yi-Fan; Ning, Wei; Lopez, Kleyser Agueda; Zhu, Yanglin; Pillsbury, Timothy; Zhang, Y. B.; Wang, Y.; Hu, Jin; Cao, Huibo; Chakoumakos, Bryan C.; Balakirev, Fedor; Weickert, Franziska; Jaime, M.; Lai, You; Yang, Kun; Sun, Jianwei; Alem, Nasim; Gopalan, Venkatraman; Chang, Cui-Zu; Samarth, N.; Liu, C. X.; McDonald, Ross; Mao, Zhiqiang

doi:10.1038/s41467-021-24369-1

Cited by 34 publications

(23 citation statements)

References 45 publications

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“…Materials with the formula MT P 2 (M is a rare-earth or alkali-earth metal, T is a transition metal, and P is a pnictogen element such as Bi and Sb) serve as versatile square-net compounds [2][3][4][5][6][7][8][9][10][11][12]. One remarkable advantage of these materials is that systematic investigation is possible by choosing the appropriate M and/or T from a wide range of materials, including nonmagnetic and magnetic elements.…”

Section: Introductionmentioning

confidence: 99%

“…One remarkable advantage of these materials is that systematic investigation is possible by choosing the appropriate M and/or T from a wide range of materials, including nonmagnetic and magnetic elements. The prominent quantum oscillation with the nontrivial Berry phase [2][3][4][5][6][7][8][9][10][11][12] and the quantum Hall effect in a bulk crystal [4,11,12] have been regarded as hallmarks of Dirac fermions derived from the Bi-or Sb-square-net layers.…”

Section: Introductionmentioning

confidence: 99%

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Magnetotransport studies of the Sb square-net compound LaAgSb2 under high pressure and rotating magnetic fields

2022

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Square-net-layered materials have attracted attention as an extended research platform of Dirac fermions and of exotic magnetotransport phenomena. In this study, we investigated the magnetotransport properties of LaAgSb 2 , which has Sb-square-net layers and shows charge density wave (CDW) transitions at ambient pressure. The application of pressure suppresses the CDWs, and above a pressure of 3.2 GPa a normal metallic phase with no CDWs is realized. By utilizing a mechanical rotator combined with a high-pressure cell, we observed the angular dependence of the Shubnikov-de Haas (SdH) oscillation up to 3.5 GPa, and we confirmed the notable two-dimensional nature of the Fermi surface. In the normal metallic phase, we also observed a remarkable field-angular-dependent magnetoresistance (MR), which exhibited a "butterflylike" polar pattern. To understand these results, we theoretically calculated the Fermi surface and conductivity tensor at the normal metallic phase. We showed that the SdH frequency and Hall coefficient calculated based on the present Fermi surface model agree well with the experiment. The transport properties in the normal metallic phase are mostly dominated by the anisotropic Dirac band, which has the highest conductivity due to linear energy dispersions. We also proposed that momentum-dependent relaxation time plays an important role in the large transverse MR and negative longitudinal MR in the normal metallic phase, which is experimentally supported by the considerable violation of Kohler's scaling rule. Although quantitatively complete reproduction was not achieved, the calculation showed that the elemental features of the butterfly MR could be reasonably explained as the geometrical effect of the Fermi surface.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Magnetotransport studies of the Sb square-net compound LaAgSb2 under high pressure and rotating magnetic fields

2022

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“…On the other hand, by considering both SOC and the canted antiferromagnetic ordering of Mn, Dirac crossings remain in a centrosymmetric I4/mmm structure scenario (i.e., assuming X square lattice) 6 . However, recent single crystal x-ray diffraction, scanning transmission electron microscopy and neutron scattering studies revealed that BaMnSb 2 actually forms an orthorhombic structure (Imm2), which is noncentrosymmetric 1,7,8 . With the Imm2 structure, Dirac cones are gapped without 7 or with the consideration of the magnetism (assuming the G-type magnetic ordering in ref.…”

Section: Introductionmentioning

confidence: 99%

“…However, recent single crystal x-ray diffraction, scanning transmission electron microscopy and neutron scattering studies revealed that BaMnSb 2 actually forms an orthorhombic structure (Imm2), which is noncentrosymmetric 1,7,8 . With the Imm2 structure, Dirac cones are gapped without 7 or with the consideration of the magnetism (assuming the G-type magnetic ordering in ref. 8 ).…”

Section: Introductionmentioning

confidence: 99%

Exploration of two surfaces observed in Weyl semimetal BaMnSb2

Zou

Huang

et al. 2022

npj Quantum Mater.

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Single crystalline BaMnSb2 is considered as a 3D Weyl semimetal with the 2D electronic structure containing Dirac cones from the Sb sheet. We report experimental investigation of low-temperature cleaved BaMnSb2 surfaces using scanning tunneling microscopy/spectroscopy and low energy electron diffraction. By natural cleavage, we find two terminations: one is Ba (above the orthorhombically distorted Sb sheet) and another Sb2 (at the surface of the Sb/Mn/Sb sandwich layer). Both terminations show the 2 × 1 surface reconstructions, with drastically different morphologies and electronic properties, however. The reconstructed structures, defect types and nature of the electronic structures of the two terminations are extensively studied. The quasiparticle interference (QPI) analysis is conducted at the energy range between −2 V and 2 V, although no interesting states are observed near the Fermi level, the surface-projected electronic band structures strongly depend on the surface termination above 1.6 V. The existence of defects can greatly modify the local density of states to create electronic phase separations on the surface in the order of tens of nm scale. Our observation on the atomic structures of the terminations and the corresponding electronic structures provides critical information towards an understanding of topological properties of BaMnSb2.

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“…The angular dependent oscillation splitting should be attributed to the dominating spin splitting of the Dirac bands. As adopted from a previous study for BaMnSb 2 [41], the g-factor is estimated to 9.2 at 0.4K by using F(1/B + -1/B − ) = (1/2)g(m*/m e ), with F=95 T (Fig. 2(f)), (1/B + -1/B − )=0.005 T −1 (Fig.…”

mentioning

confidence: 99%

Magnetic tuning of band topology evidenced by exotic quantum oscillations in the Dirac semimetal EuMnSb$_2$

Zhao¹,

Chen²,

Wang³

et al. 2022

Preprint

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Interplay between magnetism and electronic band topology is of central current interest in topological matter research. We use quantum oscillations as powerful tool to probe the evolution of band topology in the Dirac semimetal EuMnSb2. The Eu local 4f magnetic moments display different antiferromagnetic states below 25 K and a field-polarized phase above 16 T. Upon cooling from 65 K into the field-polarized state, an exotic temperature dependent shift of oscillation peaks arises, accompanied by the development of non-trivial Berry phase and huge spin splitting. Bandstructure calculations confirm the change from trivial to non-trivial band topology induced by the ferromagnetic Eu state, classifying EuMnSb2 as unique magnetic topological semimetal.

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Spin-valley locking and bulk quantum Hall effect in a noncentrosymmetric Dirac semimetal BaMnSb2

Cited by 34 publications

References 45 publications

Magnetotransport studies of the Sb square-net compound LaAgSb2 under high pressure and rotating magnetic fields

Magnetotransport studies of the Sb square-net compound LaAgSb2 under high pressure and rotating magnetic fields

Exploration of two surfaces observed in Weyl semimetal BaMnSb2

Magnetic tuning of band topology evidenced by exotic quantum oscillations in the Dirac semimetal EuMnSb$_2$

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