Field-effect transistor and giant magnetoresistance effect based on optically induced antichiral edge state in graphene

Lü, Xiao-Long; Liu, Gang; Yang, Jia-En; Xie, Hang

doi:10.1063/5.0189578

Applied Physics Letters

2024

DOI: 10.1063/5.0189578

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Field-effect transistor and giant magnetoresistance effect based on optically induced antichiral edge state in graphene

Xiao-Long Lü,

Gang Liu,

Jia-En Yang

et al.

Abstract: We propose a peculiar method to induce the antichiral edge state (AES) based on off-resonant circularly polarized (ORCP) light and further study its edge-state transitions and transport properties in zigzag graphene nanoribbon. The results show that the vertical irradiation of the ORCP light on two boundaries of the system could be regarded as a modified Haldane model for inducing the AES. In particular, under the antiferromagnetic (AFM) exchange field, the system with the AES can be controlled by an electric … Show more

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Cited by 2 publications

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Topological and chiral matter—Physics and applications

Vergniory,

Kondo,

Kotov

et al. 2024

Applied Physics Letters

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Topological and chiral matter—Physics and applications

Vergniory,

Kondo,

Kotov

et al. 2024

Applied Physics Letters

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Phase diagrams and topological mixed edge states in silicene with intrinsic and extrinsic Rashba effects

Lü,

Zhang,

et al. 2024

Phys. Rev. Research

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We investigate the topological phases and corresponding edge states in silicene with fixed intrinsic and extrinsic Rashba spin-orbit couplings. The results show that silicene can exhibit four distinct topological phases, such as two types of valley-polarized quantum anomalous Hall effect (QAHE) and two types of QAHE that can be effectively controlled by the exchange field and electric field. In addition, these topological phases only correspond to the valley edge states distributed at the boundary of silicene. In particular, when the off-resonant circularly polarized (ORCP) light is further considered, silicene can host richer topological phases that are characterized by the Chern numbers from C=−3 to C=3, where the corresponding mixed edge states—where the valley and nonvalley edge states could coexist—can remarkably appear. More interestingly, the special higher Chern numbers C=±3 determine two valley edge states and one nonvalley edge state, with the right-moving or left-moving direction. These peculiar edge states are attributed to the ORCP light destroying the collapse of the Dirac cones that the valley edge states bridge. Additionally, silicene can experience multiple edge-state transitions for identical Chern numbers C=±2 between the valley edge state, nonvalley edge state, and two types of mixed edge state, under the ORCP light. This work may provide a platform and point of view for investigating other forms of topological edge state and is beneficial for designing multifunctional topological devices. Published by the American Physical Society 2024

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Field-effect transistor and giant magnetoresistance effect based on optically induced antichiral edge state in graphene

Cited by 2 publications

References 41 publications

Topological and chiral matter—Physics and applications

Topological and chiral matter—Physics and applications

Phase diagrams and topological mixed edge states in silicene with intrinsic and extrinsic Rashba effects

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