Shengjie Zheng scite author profile

Topologically gapless edge states, characterized by topological invariants and Berry's phases of bulk energy bands, provide amazing techniques to robustly control the reflectionless propagation of electrons, photons and phonons. Recently, a new family of topological phases, dictated by the bulk polarization, has been observed, leading to the discovery of the higher-order topological insulators (HOTIs). So far, the HOTIs are only demonstrated in discrete mechanical and electromagnetic systems and electrical circuits with the quantized quadrupole polarization.Here, we realize the higher-order topological states in a two-dimensional (2D) continuous elastic system whose energy bands can be well described. We experimentally observe the gapped onedimensional (1D) edge states, the trivially gapped zero-dimensional (0D) corner states and the topologically protected 0D corner states. Compared with the trivial corner modes, the topological ones, immunizing against defects, are robustly localized at the obtuse-angled but not the acuteangled corners. The topological shape-dependent corner states open a new route for the design of the topologically-protected but reconfigurable 0D local eigenmodes and provide an excellent platform for the topological transformation of elastic energy among 2D bulk, 1D edge and 0D corner modes.

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Topological phononic insulator with robust pseudospin-dependent transport

Xia

et al. 2017

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Topological phononic states, facilitating acoustic unique transports immunizing to defects and disorders, have significantly revolutionized our scientific cognition of acoustic wave systems. Up to now, the theoretical and experimental demonstrations of topologically protected one-way transports with pseudospin states in a phononic crystal beyond the graphene lattice with C 6v symmetry are still unexploited. Furthermore, the tunable topological states, in form of robust reconfigurable acoustic pathways, have been evaded in the topological phononic insulators. Here, we realize a topological phase transition in the double Dirac degenerate cone of rotatable triangular phononic crystals with C 3v symmetry, by introducing the zone folding mechanism. Along a topological domain wall between two portions of phononic crystals with distinct topological phases, we experimentally observe the quantum spin Hall (QSH) effect for xiabz2013@hnu.edu.cn (Baizhan Xia) djyu@hnu.edu.cn (Dejie Yu) liujian@hnu.edu.cn (Jian Liu)

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Observation of valleylike edge states of sound at a momentum away from the high-symmetry points

et al. 2018

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Topologically protected one-way transportation of sound, mimicking the topological properties of the condensed matter, has received greatly attentions. Thus far, the topological phases and the topological edge states of sound are yielded in the vicinity of the Dirac cones fixed at the high symmetric points of the Brillouin zone. Here, we present a new type of the phononic topological insulator in the square lattice with position-variational Dirac cones along the high symmetric lines. The emergence of such Dirac cones, characterized by the vortex structure in a momentum space, is attributed to the unavoidable band crossing protected by the mirror symmetry. By rotating the square columns, these Dirac points are lifted and a complete band gap is induced because of the mirror-symmetry-breaking. Along the topological domain wall between the phononic crystals (PhCs) with the distinct topological phases stemming from the mirror symmetry inversion, we obtain a topological edge state for the neutral scalar sound which is absence of the intrinsic polarization and is uncoupled from an external field. Within a wide rotational range of the square column, the topological edge state in our PhCs evolves from xiabz2013@hnu.edu.cn (Baizhan Xia) djyu@hnu.edu.cn (Dejie Yu)

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Improved tunicate swarm algorithm: Solving the dynamic economic emission dispatch problems

Liu

Tseng

et al. 2021

Applied Soft Computing

116

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Observation of fractal higher-order topological states in acoustic metamaterials

Zheng

Man²,

Kong³

et al. 2022

Science Bulletin

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Shengjie Zheng

Elastic Higher-Order Topological Insulator with Topologically Protected Corner States

Topological phononic insulator with robust pseudospin-dependent transport

Observation of valleylike edge states of sound at a momentum away from the high-symmetry points

Improved tunicate swarm algorithm: Solving the dynamic economic emission dispatch problems

Observation of fractal higher-order topological states in acoustic metamaterials

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