Helicity-protected ultrahigh mobility Weyl fermions in NbP

Wang, Zhen; Zheng, Yi; Shen, Zhixuan; Lu, Yunhao; Fang, Hanyan; Sheng, Feng; Zhou, Yi; Yang, Xiukang; Li, Y. P.; Feng, Chunmu; Xu, Zhu-An

doi:10.1103/physrevb.93.121112

Cited by 203 publications

(181 citation statements)

References 34 publications

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“…This discovery paves the way for realizing the many predicted exotic topological quantum phenomena of Weyl semimetals in the TaAs class of materials 9,[25][26][27][28][29][30][31][32][33][34] . For any ongoing [35][36][37][42][43][44][45][46][47][48][49][50][51] or future experiments on these materials, systematic knowledge of the band structure and Fermi surface is crucial and fundamental in understanding and interpreting their data and observations. However, surprisingly, a comprehensive study of the band structure details of the TaAs Weyl semimetal family has been lacking.…”

Section: 61mentioning

confidence: 99%

Fermi surface interconnectivity and topology in Weyl fermion semimetals TaAs, TaP, NbAs, and NbP

et al. 2015

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The family of binary compounds including TaAs, TaP, NbAs, and NbP was recently discovered as the first realization of Weyl semimetals. In order to develop a comprehensive description of the charge carriers in these Weyl semimetals, we performed a detailed and systematic electronic band structure calculations which reveal the nature of Fermi surfaces and their complex interconnectivity in TaAs, TaP, NbAs, and NbP. Our work report the first comparative and comprehensive study of Fermi surface topology and band structure details of all known members of the Weyl semimetal family, and hence provides the fundamental knowledge for realizing the many predicted exotic topological quantum physics of Weyl semimetals based on the TaAs class of materials.

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Section: 61mentioning

confidence: 99%

Fermi surface interconnectivity and topology in Weyl fermion semimetals TaAs, TaP, NbAs, and NbP

et al. 2015

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“…While the linear field dependent magnetoresistance as observed in graphene [1], topological insulators Bi 2 Te 3 and Bi 2 Se 3 [2,3], Ag 2+δ Te/Se [4,5], Dirac semimetals Cd 3 As 2 [6,7] and Na 3 Bi [8], and type-I Weyl semimetals NbAs(P) [9][10][11] and TaAs [12,13] is explained based on the linear dispersive Dirac states present near the Fermi level [14,15], the quadratic field dependent MR as observed in the type-II Weyl semimetals WTe 2 and MoTe 2 [16,17], LaSb [18], ZrSiS [19], and Bi [20] is explained based on the charge compensation [16]. However, the role of charge compensation for the XMR of these compounds is still not clear as some reports recently demonstrated quadratic field dependent MR without charge balance [21,22].…”

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confidence: 99%

Possible origin of linear magnetoresistance: Observation of Dirac surface states in layered PtBi2

et al. 2018

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The nonmagnetic compounds showing extremely large magnetoresistance are attracting a great deal of research interests due to their potential applications in the field of spintronics. PtBi2 is one of such interesting compounds showing large linear magnetoresistance (MR) in its both the hexagonal and pyrite crystal structure. We use angle-resolved photoelectron spectroscopy (ARPES) and density functional theory (DFT) calculations to understand the mechanism of liner MR observed in the hexagonal PtBi2. Our results uncover for the first time linear dispersive surface Dirac states at theΓ-point, crossing Fermi level with node at a binding energy of ≈ 900 meV, in addition to the previously reported Dirac states at theM -point in the same compound. We further notice from our dichroic measurements that these surface states show an asymmetric spectral intensity when measured with left and right circularly polarized light, hinting at a substantial spin polarization of the bands. Following these observations, we suggest that the linear dispersive Dirac states at thē Γ andM -points are likely to play a crucial role for the linear field dependent magnetoresistance recorded in this compound. Bi [20] is explained based on the charge compensation [16]. However, the role of charge compensation for the XMR of these compounds is still not clear as some reports recently demonstrated quadratic field dependent MR without charge balance [21,22]. Moreover, the theory based on the impurity scattering or crystal disorder is inevitably brought into the above two cases and as well to the subquadratic field dependent MR [23][24][25]. The other existing mechanisms include metal-insulator transition [26][27][28][29][30] and strong spin-orbit interactions [31,32]. Thus, there is no clear consensus yet on the mechanism of magnetoresistance in the nonmagnetic solids.PtBi 2 is a very interesting compound as it shows MR in both the hexagonal [33] and pyrite structures [34]. Astonishingly, the pyrite PtBi 2 has been found to show the highest MR observed among the known nonmagnetic metals so far [4-7, 10, 16, 17], which also has been predicted as a 3-dimensional Dirac semimetal [35]. Therefore, understating the mechanism of extremely large MR in this compound is essential due to its potential applications. While in the pyrite structure the extremely large MR is attributed to its semimetalic nature [34], the large linear MR observed in the hexagonal phase is explained based on the crystal disorder theory [33,36]. Here, we report on the electronic structure of hexagonal PtBi 2 using the ARPES technique and first-principles calculations. Our studies suggest that PtBi 2 has two different surface terminations as the experimental band structure looks different from different cleavages. Our ARPES measurements demonstrate linear dispersive surface Dirac states near the Fermi level with a node at ≈ 150 meV below the Fermi level (E F ) at theM -point with a 6-fold rotational symmetry in the ΓM K plane. Thus, there exists 6 Dirac cones of this type in a Bril...

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“…Recently the first WSM materials (Ta,Nb)(As,P) have been discovered by addressing the Fermi arcs in angleresolved photoemission spectra (ARPES) [14][15][16][17][18][19][20] , which was originally predicted by band structure calculations 21,22 . Meanwhile a great amount of efforts have also been devoted to their magneto-transport properties [23][24][25][26][27][28][29] , such as extremely large, positive transverse MR 23 and large, negative longitudinal MR 24,29 . These family of WSMs exhibit ideal Weyl cones in the bulk band structure, i.e.…”

Section: Introductionmentioning

confidence: 99%

Prediction of Weyl semimetal in orthorhombicMoTe2

et al. 2015

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We investigate the orthorhombic phase (Td) of layered transition-metal-dichalcogenide MoTe2 as the Weyl semimetal candidate. MoTe2 exhibits four pairs of Weyl points lying slightly above (∼ 6 meV) the Fermi energy in the bulk band structure. Different from its cousin WTe2 that was predicted to be a type-II Weyl semimetal recently, the spacing between each pair of Weyl points is found to be as large as 4 percent of the reciprocal lattice in MoTe2 (six times larger than that of WTe2). When projected to the surface, Weyl points are connected by Fermi arcs, which can be easily accessed by ARPES due to the large Weyl point separation. In addition, we show that the correlation effect or strain can drive MoTe2 from type-II to type-I Weyl semimetal.

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Helicity-protected ultrahigh mobility Weyl fermions in NbP

Cited by 203 publications

References 34 publications

Fermi surface interconnectivity and topology in Weyl fermion semimetals TaAs, TaP, NbAs, and NbP

Fermi surface interconnectivity and topology in Weyl fermion semimetals TaAs, TaP, NbAs, and NbP

Possible origin of linear magnetoresistance: Observation of Dirac surface states in layered PtBi2

Prediction of Weyl semimetal in orthorhombicMoTe2

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