Phononic Weyl Nodal Straight Lines in High-Temperature Superconductor MgB$_2$

Xie, Qing; Li, Jiangxu; Liu, Min; Wang, Lei; Li, Dianzhong; Li, Yiyi; Chen, Xing-Qiu

doi:10.48550/arxiv.1801.04048

Cited by 5 publications

(9 citation statements)

References 58 publications

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“…The concept of topology from the electronic bandstructure has been successfully extended to the vibrational bandstructure of materials [89][90][91][92][93]. In recent works, topologically protected band-crossings have been reported in the phonon spectrum of solid state crystals [41,[94][95][96][97]. Soon after the theoretical prediction of double-Weyl phonons in the phonon spectrum of transition-metal monosilicides MSi (M=Fe, Co, Mn, Re, Ru) [94], Miao et al [98] experimentally reported the first observation of double Weyl points in FeSi by means of inelastic x-ray scattering measurements.…”

Section: Topology Of Phonons In Triple-point Metalsmentioning

confidence: 99%

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Topology of triple-point metals*

2019

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We discuss and illustrate the appearance of topological fermions and bosons in triple-point metals, where a band crossing of three electronic bands occurs close to the Fermi level. Topological bosons appear in the phonon spectrum of certain triple-point metals, depending on the mass of atoms that form the binary triple-point metal. We first provide a classification of possible triple-point electronic topological phases possible in crystalline compounds and discuss the consequences of these topological phases, seen in Fermi arcs, topological Lifshitz transitions and transport anomalies.Then we show how the topological phase of phonon modes can be extracted and proven for relevant compounds. Finally, we show how the interplay of electronic and phononic topologies in triple-point metals puts these metallic materials into the list of the most efficient metallic thermoelectrics known to date.

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Section: Topology Of Phonons In Triple-point Metalsmentioning

confidence: 99%

“…Recently, topologically protected Weyl nodal lines have been predicted in the phonon spectrum of bulk MgB 2 [97].…”

Section: Topology Of Phonons In Triple-point Metalsmentioning

confidence: 99%

Topology of triple-point metals*

2019

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“…Since the theoretical prediction and experimental realization of Weyl semimetal state in the TaAs class of compounds [1][2][3][4], Weyl materials including Weyl fermions [5][6][7][8][9][10][11][12], Weyl photonic crystal [13,14] and Weyl phononic crystal [15][16][17][18][19][20] with novel surface states have attracted significant interest recently. The spin-1/2 Weyl points (WPs) emerging in solids without time reversal symmetry or inversion symmetry are the twofold degenerated crossing points of two linearly dispersing bands in the three directions of momentum space [21,22].…”

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Ideal type-II Weyl phonons in wurtzite CuI

et al. 2019

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Weyl materials exhibiting topologically nontrivial touching points in band dispersion pave the way to exotic transport phenomena and novel electronic devices.Here, we demonstrate the signature of ideal type-II Weyl phase in phonon dispersion of solids through first-principles investigations. Type-II phononic Weyl phase is manifested in noncentrosymmetric wurtzite CuI by six pairs of Weyl points (WPs) in the = 0.0 plane. On the iodine-terminated surface of the crystal, very clean surface arcs are readily detectable. Each pair of WPs connected by open surface arcs is well separated by a large distance of 0.26 Å −1 , ten times larger than that in TaAs. The opposite chirality of WPs with quantized Berry curvature produces Weyl phonon Hall effect, in analogy to valley Hall effect of electrons. Such ideal type-II Weyl phase are readily observable in experiment, providing a unique platform to study novel thermal transport properties distinct from type-I Weyl phase.

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“…Therefore, all these four crossing points of PW1, PW2, PW3, and PW4 are phononic Weyl-like points. It needs to be emphasized that the general Weyl point is in the 3D conical shape [23], as already emphasized in many electronic Weyl semimetals and several phononic Weyl materials [56][57][58][59][60][61][62]. However, given the fact that it is not physically allowed for any 3D shape for graphene due to its single layer structure and the phononic band is spinless, it is reason- able to define these crossings as Weyl-like phonons.…”

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confidence: 99%

“…Moreover, it needs to be emphasized that for PW4 no edge states can be clearly observed because the PW4-induced topologically protected phononic edge states fully overlap with the edge projection from the phonon dispersions of the pristine graphene. In the third, in similarity to the nodal lines in 3D crystals which exhibits nontrivial drumhead-like surface states for BaSn 2 , Ca 3 P, TlTaSe 2 and TiSi, ZrSiS [63][64][65][66][67] and the phononic Weyl nodal line MgB 2 [60], the existence of PNL of the pristine graphene at 24.38 THz induces the straight-line edge states, simultaneously, with an arc-like going-downwards parabola in its frequencies upon the q momentum, as shown in Fig. 4(d).…”

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confidence: 99%

Topological Weyl-like Phonons and Nodal Line Phonons in Graphene

Li,

Wang,

Liu

et al. 2019

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By means of first-principles calculations and modeling analysis, we have predicted that the traditional 2Dgraphene hosts the topological phononic Weyl-like points (PWs) and phononic nodal line (PNL) in its phonon spectrum. The phonon dispersion of graphene hosts three type-I PWs (both PW1 and PW2 at the BZ corners K and K', and PW3 locating along the Γ-K line), one type-II PW4 locating along the Γ-M line, and one PNL surrounding the centered Γ point in the q x,y plane. The calculations further reveal that Berry curvatures are vanishingly zero throughout the whole BZ, except for the positions of these four pairs of Weyl-like phonons, at which the non-zero singular Berry curvatures appear with the Berry phase of π or -π, confirming its topological non-trivial nature. The topologically protected non-trivial phononic edge states have been also evidenced along both the zigzag-edged and armchair-edged boundaries. These results would pave the ways for further studies of topological phononic properties of graphene, such as phononic destructive interference with a suppression of backscattering and intrinsic phononic quantum Hall-like effects.

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Phononic Weyl Nodal Straight Lines in High-Temperature Superconductor MgB$_2$

Cited by 5 publications

References 58 publications

Topology of triple-point metals*

Topology of triple-point metals*

Ideal type-II Weyl phonons in wurtzite CuI

Topological Weyl-like Phonons and Nodal Line Phonons in Graphene

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