Coriolis force induced topological order for classical mechanical vibrations

Yao-ting Wang; Pi-gang Luan; Shuang Zhang

doi:10.1088/1367-2630/17/7/073031

Coriolis force induced topological order for classical mechanical vibrations

Yao-ting Wang, Pi-gang Luan, Shuang Zhang

Physics and Astronomy

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73 Citations (Scopus)

296 Downloads (Pure)

Abstract

We show that topological order and vibrational edge modes can exist in a classical mechanical system consisting of a two-dimensional honeycomb lattice of masses and springs. The band structure shows the existence of Dirac cones and unconventional edge states that are similar to the vibrational modes in graphene. Interestingly, as the system is placed on a constantly rotational coordinate system, the Coriolis force resulting from the non-inertial reference frame introduces time-reversal symmetry breaking and leads to topologically nontrivial band gaps. The nontrivial topological orders are further verified by the calculation of Chern numbers for corresponding bands.

Original language	English
Article number	073031
Journal	New Journal of Physics
Volume	17
Issue number	7
DOIs	https://doi.org/10.1088/1367-2630/17/7/073031
Publication status	Published - 31 Jul 2015

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10.1088/1367-2630/17/7/073031

Wang_et_al_2015_Coriolis_force_induced_NJP
Eligibility for repository : checked 27/10/2015
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http://stacks.iop.org/1367-2630/17/i=7/a=073031?key=crossref.35acf3822edb030aced42dfe0b6025d2

NSF Materials World Network: Classical and Quantum Optical Metamaterials by Combining Top-down and Bottom-Up Fabrication Techniques
Zhang, S. (Principal Investigator)
Engineering & Physical Science Research Council
1/02/13 → 31/01/16
Project: Research Councils

Cite this

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title = "Coriolis force induced topological order for classical mechanical vibrations",

abstract = "We show that topological order and vibrational edge modes can exist in a classical mechanical system consisting of a two-dimensional honeycomb lattice of masses and springs. The band structure shows the existence of Dirac cones and unconventional edge states that are similar to the vibrational modes in graphene. Interestingly, as the system is placed on a constantly rotational coordinate system, the Coriolis force resulting from the non-inertial reference frame introduces time-reversal symmetry breaking and leads to topologically nontrivial band gaps. The nontrivial topological orders are further verified by the calculation of Chern numbers for corresponding bands.",

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N2 - We show that topological order and vibrational edge modes can exist in a classical mechanical system consisting of a two-dimensional honeycomb lattice of masses and springs. The band structure shows the existence of Dirac cones and unconventional edge states that are similar to the vibrational modes in graphene. Interestingly, as the system is placed on a constantly rotational coordinate system, the Coriolis force resulting from the non-inertial reference frame introduces time-reversal symmetry breaking and leads to topologically nontrivial band gaps. The nontrivial topological orders are further verified by the calculation of Chern numbers for corresponding bands.

AB - We show that topological order and vibrational edge modes can exist in a classical mechanical system consisting of a two-dimensional honeycomb lattice of masses and springs. The band structure shows the existence of Dirac cones and unconventional edge states that are similar to the vibrational modes in graphene. Interestingly, as the system is placed on a constantly rotational coordinate system, the Coriolis force resulting from the non-inertial reference frame introduces time-reversal symmetry breaking and leads to topologically nontrivial band gaps. The nontrivial topological orders are further verified by the calculation of Chern numbers for corresponding bands.

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Coriolis force induced topological order for classical mechanical vibrations

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NSF Materials World Network: Classical and Quantum Optical Metamaterials by Combining Top-down and Bottom-Up Fabrication Techniques

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