Type-II Dirac semimetals in the 
<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML"><mml:mrow><mml:msub><mml:mi>YPd</mml:mi><mml:mn>2</mml:mn></mml:msub><mml:mi>Sn</mml:mi></mml:mrow></mml:math>
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Guo, Peng‐Jie; Yang, Huan-Cheng; Liu, Kai; Lu, Zhong-Yi

doi:10.1103/physrevb.95.155112

Cited by 56 publications

(30 citation statements)

References 65 publications

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“…Furthermore, the presence of trigonal symmetry is not a pre-requisite. The 'Heusler' alloys (O h ) ({Y, Sc,}Pd 2 Sn), ({Zr, Hf,}Pd 2 Al) and ({Zr, Hf,}Ni 2 Al), have been recently verified to host type-II bulk Dirac cones at the Fermi level [36]. At higher energies (approximately 1 eV below the Fermi level in YPd 2 Sn), however, calculations ( Fig.…”

Section: Universality Of Kz Mediated Band Inversionsmentioning

confidence: 99%

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A general route to form topologically-protected surface and bulk Dirac fermions along high-symmetry lines

Clark¹,

Mazzola²,

Marković³

et al. 2019

Electron. Struct.

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The band inversions that generate the topologically non-trivial band gaps of topological insulators and the isolated Dirac touching points of three-dimensional Dirac semimetals generally arise from the crossings of electronic states derived from different orbital manifolds. Recently, the concept of single orbital-manifold band inversions occurring along high-symmetry lines has been demonstrated, stabilising multiple bulk and surface Dirac fermions. Here, we discuss the underlying ingredients necessary to achieve such phases, and discuss their existence within the family of transition metal dichalcogenides. We show how their three-dimensional band structures naturally produce only small kz projected band gaps, and demonstrate how these play a significant role in shaping the surface electronic structure of these materials. We demonstrate, through spin-and angle-resolved photoemission and density functional theory calculations, how the surface electronic structures of the group-X TMDs PtSe2 and PdTe2 are host to up to five distinct surface states, each with complex band dispersions and spin textures. Finally, we discuss how the origin of several recentlyrealised instances of topological phenomena in systems outside of the TMDs, including the iron-based superconductors, can be understood as a consequence of the same underlying mechanism driving kz-mediated band inversions in the TMDs.

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Section: Universality Of Kz Mediated Band Inversionsmentioning

confidence: 99%

“…(a) Orbitally projected band structure calculation of β-CuI (D 3d ) adapted from[35]. (b) Band structure calculations of YPd2Sn (O h ) reprinted with permission from[36]. Copyright (2019) by the American Physical Society.…”

mentioning

confidence: 99%

A general route to form topologically-protected surface and bulk Dirac fermions along high-symmetry lines

Clark¹,

Mazzola²,

Marković³

et al. 2019

Electron. Struct.

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“…In addition, since accidental Dirac points are located at k-points with lower symmetry (compared with essential ones), the dispersions around them are less constrained. It is possible to have the Dirac cone completely tipped over along certain direction [22,23], realizing a so-called type-II Dirac point [24], which has been identified in VAl 3 [24], PdTe 2 [25][26][27], PtSe 2 family [28][29][30] and others [31][32][33]. Fascinating yet distinct physics have been proposed for type-I and type-II points, and it has been theoretically argued in the context of Weyl points that when both types coexist in a single hybrid material, even more interesting effects could appear [34,35].…”

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confidence: 99%

Ternary wurtzite CaAgBi materials family: A playground for essential and accidental, type-I and type-II Dirac fermions

Chen

Wang

Liu

et al. 2017

Phys. Rev. Materials

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Based on their formation mechanisms, Dirac points in three-dimensional systems can be classified as accidental or essential. The former can be further distinguished into type-I and type-II, depending on whether the Dirac cone spectrum is completely tipped over along certain direction. Here, we predict the coexistence of all three kinds of Dirac points in the low-energy band structure of CaAgBifamily materials with a stuffed Wurtzite structure. Two pairs of accidental Dirac points reside on the rotational axis, with one pair being type-I and the other pair type-II; while another essential Dirac point is pinned at the high symmetry point on the Brillouin zone boundary. Due to broken inversion symmetry, the band degeneracy around accidental Dirac points is completely lifted except along the rotational axis, which may enable the splitting of chiral carriers at a ballistic p-n junction with a double negative refraction effect. We clarify their symmetry protections, and find both the Dirac-cone and Fermi arc topological surface states.Topological semimetals have been attracting tremendous interest in current research [1][2][3], partly because they offer a convenient platform to explore the intriguing physics of high-energy elementary particles. For example, Weyl semimetals possess linearly-dispersing twofold-degenerate Weyl points close to Fermi energy [4][5][6][7][8][9][10]. Each Weyl point has a definite chirality of ±1, around which the quasiparticle excitations mimic the relativistic Weyl fermions [11,12]. Two Weyl points with opposite chirality would be unstable towards gap-opening when they meet at the same k-point, unless there exists additional symmetry protection, such as the case in so-called Dirac semimetals [13], in which stable Dirac points with four-fold-degeneracy make it possible to simulate massless Dirac fermions.Dirac points can be classified as accidental or essential [14] (see Fig. 1). Accidental Dirac points require band inversion (which is in a sense accidental) and are stablized by certain symmorphic crystalline symmetries such as rotation, so such Dirac points typically reside on high-symmetry lines. Examples include the experimentally confirmed Dirac semimetals Na 3 Bi [15,16] [17][18][19][20]. Essential Dirac points do not need band inversion, and their presence is solely determined by certain nonsymmorphic symmtries at high-symmetry points on the boundary of the Brillouzin zone (BZ). Examples include the first few proposals such as β-cristobalite BiO 2 [13] and several Bi-containing distorted spinels [21]. Accidental Dirac points can be removed by reverting the band ordering without changing the symmetry, whereas essential Dirac points cannot. In addition, since accidental Dirac points are located at k-points with lower symmetry (compared with essential ones), the dispersions around them are less constrained. It is possible to have the Dirac cone completely tipped over along certain direction [22,23] [31][32][33]. Fascinating yet distinct physics have been proposed for type-I and type-II po...

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“…While type-I Dirac cones (DCs) are common in honeycomb configurations and other two-(2D) and three-dimensional (3D) materials [3][4][5][6][7][8][9][10][11][12][13][14], this is not the case for type-II DCs. In recent studies, type-II Dirac semimetals [26][27][28][29] and 3D topological photonic crystal structures [30] have been demonstrated. Along these lines, of interest would be to identify 2D photonic systems with analogous dispersion characteristics, akin to those proposed in solid state physics [31,32].…”

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confidence: 99%

Emergence of Type-II Dirac Points in Graphynelike Photonic Lattices

et al. 2017

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We theoretically demonstrate that a type-II class of tilted Dirac cones can emerge in generalized two-dimensional anisotropic lattice arrangements. This is achieved by introducing a special set of graphyne-like exchange bonds by means of which the complete spectrum of the underlying Weyl Hamiltonian can be realized. Our ab-initio calculations demonstrate a unique class of eigensolutions corresponding to a type-II class of Dirac fermionic excitations. Based on our approach, one can systematically synthesize a wide range of strongly anisotropic band diagrams having tilted Dirac cones with variable location and orientation. Moreover, we show that asymmetric conical diffraction as well as edge states, can arise in these configurations. Our results can provide a versatile platform to observe, for the first time, optical transport around type-II Dirac points in two-dimensional optical settings under linear, nonlinear, and non-Hermitian conditions.

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Type-II Dirac semimetals in the YPd2Sn class

Cited by 56 publications

References 65 publications

A general route to form topologically-protected surface and bulk Dirac fermions along high-symmetry lines

A general route to form topologically-protected surface and bulk Dirac fermions along high-symmetry lines

Ternary wurtzite CaAgBi materials family: A playground for essential and accidental, type-I and type-II Dirac fermions

Emergence of Type-II Dirac Points in Graphynelike Photonic Lattices

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