Four-dimensional quantum hall effect in a two-dimensional quasicrystal

Yaacov E. Kraus; Zohar Ringel; Oded Zilberberg

doi:https://doi.org/10.1103/PhysRevLett.111.226401

Four-dimensional quantum hall effect in a two-dimensional quasicrystal

Yaacov E. Kraus, Zohar Ringel, Oded Zilberberg

Department of Condensed Matter Physics

Weizmann Institute of Science

Research output: Contribution to journal › Article › peer-review

Abstract

One-dimensional (1D) quasicrystals exhibit physical phenomena associated with the 2D integer quantum Hall effect. Here, we transcend dimensions and show that a previously inaccessible phase of matter - the 4D integer quantum Hall effect - can be incorporated in a 2D quasicrystal. Correspondingly, our 2D model has a quantized charge-pump accommodated by an elaborate edge phenomena with protected level crossings. We propose experiments to observe these 4D phenomena, and generalize our results to a plethora of topologically equivalent quasicrystals. Thus, 2D quasicrystals may pave the way to the experimental study of 4D physics.

Original language	English
Article number	226401
Number of pages	5
Journal	Physical Review Letters
Volume	111
Issue number	22
DOIs	https://doi.org/10.1103/PhysRevLett.111.226401
State	Published - 25 Nov 2013

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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title = "Four-dimensional quantum hall effect in a two-dimensional quasicrystal",

abstract = "One-dimensional (1D) quasicrystals exhibit physical phenomena associated with the 2D integer quantum Hall effect. Here, we transcend dimensions and show that a previously inaccessible phase of matter - the 4D integer quantum Hall effect - can be incorporated in a 2D quasicrystal. Correspondingly, our 2D model has a quantized charge-pump accommodated by an elaborate edge phenomena with protected level crossings. We propose experiments to observe these 4D phenomena, and generalize our results to a plethora of topologically equivalent quasicrystals. Thus, 2D quasicrystals may pave the way to the experimental study of 4D physics.",

author = "Kraus, {Yaacov E.} and Zohar Ringel and Oded Zilberberg",

note = "Minerva Foundation of the DFG; US-Israel BSFWe thank E. Berg and Y. Lahini for fruitful discussions. We acknowledge the Minerva Foundation of the DFG and the US-Israel BSF for financial support. Authors' names appear in alphabetical order.",

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AU - Kraus, Yaacov E.

AU - Ringel, Zohar

AU - Zilberberg, Oded

N1 - Minerva Foundation of the DFG; US-Israel BSFWe thank E. Berg and Y. Lahini for fruitful discussions. We acknowledge the Minerva Foundation of the DFG and the US-Israel BSF for financial support. Authors' names appear in alphabetical order.

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N2 - One-dimensional (1D) quasicrystals exhibit physical phenomena associated with the 2D integer quantum Hall effect. Here, we transcend dimensions and show that a previously inaccessible phase of matter - the 4D integer quantum Hall effect - can be incorporated in a 2D quasicrystal. Correspondingly, our 2D model has a quantized charge-pump accommodated by an elaborate edge phenomena with protected level crossings. We propose experiments to observe these 4D phenomena, and generalize our results to a plethora of topologically equivalent quasicrystals. Thus, 2D quasicrystals may pave the way to the experimental study of 4D physics.

AB - One-dimensional (1D) quasicrystals exhibit physical phenomena associated with the 2D integer quantum Hall effect. Here, we transcend dimensions and show that a previously inaccessible phase of matter - the 4D integer quantum Hall effect - can be incorporated in a 2D quasicrystal. Correspondingly, our 2D model has a quantized charge-pump accommodated by an elaborate edge phenomena with protected level crossings. We propose experiments to observe these 4D phenomena, and generalize our results to a plethora of topologically equivalent quasicrystals. Thus, 2D quasicrystals may pave the way to the experimental study of 4D physics.

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Four-dimensional quantum hall effect in a two-dimensional quasicrystal

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