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Deterministic scheme for two-dimensional type-II Dirac points and experimental realization in acoustics

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arxiv 1907.06850 v3 pith:VVXJLFN4 submitted 2019-07-16 cond-mat.mes-hall physics.class-ph

Deterministic scheme for two-dimensional type-II Dirac points and experimental realization in acoustics

classification cond-mat.mes-hall physics.class-ph
keywords diracpointsdeterministictype-iinodalschemetheyacoustics
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Low-energy electrons near Dirac/Weyl nodal points mimic massless relativistic fermions. However, as they are not constrained by Lorentz invariance, they can exhibit tipped-over type-II Dirac/Weyl cones which provide highly anisotropic physical properties and responses, creating unique possibilities. Recently, they have been observed in several quantum and classical systems. Yet, there is still no simple and deterministic strategy to realize them since their nodal points are accidental degeneracies, unlike symmetry-guaranteed type-I counterparts. Here, we propose a band-folding scheme for constructing type-II Dirac points, and we use a tight-binding analysis to unveil its generality and deterministic nature. Through realizations in acoustics, type-II Dirac points are experimentally visualized and investigated using near-field mappings. As a direct effect of tipped-over Dirac cones, strongly tilted kink states originating from their valley-Hall properties are also observed. This deterministic scheme could serve as platform for further investigations of intriguing physics associated with various strongly Lorentz-violating nodal points.

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