Ideal Weyl points and helicoid surface states in artificial photonic crystal structures

Biao Yang; Qinghua Guo; Ben Tremain; Rongjuan Liu; Lauren E. Barr; Qinghui Yan; Wenlong Gao; Hongchao Liu; Yuanjiang Xiang; Jing Cheng; Chen Fang; Alastair Hibbins; Ling Lu; Shuang Zhang

doi:10.1126/science.aaq1221

Ideal Weyl points and helicoid surface states in artificial photonic crystal structures

Biao Yang, Qinghua Guo, Ben Tremain, Rongjuan Liu, Lauren E. Barr, Qinghui Yan, Wenlong Gao, Hongchao Liu, Yuanjiang Xiang, Jing Cheng, Chen Fang, Alastair Hibbins, Ling Lu, Shuang Zhang

Physics and Astronomy

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Abstract

Weyl points are the crossings of linearly dispersing energy bands of three-dimensional crystals, providing the opportunity to explore a variety of intriguing phenomena such as topologically protected surface states and chiral anomalies. However, the lack of an ideal Weyl system in which the Weyl points all exist at the same energy and are separated from any other bands poses a serious limitation to the further development of Weyl physics and potential applications. By experimentally characterizing a microwave photonic crystal of saddle-shaped metallic coils, we observed ideal Weyl points that are related to each other through symmetry operations. Topological surface states exhibiting helicoidal structure have also been demonstrated. Our system provides a photonic platform for exploring ideal Weyl systems and developing possible topological devices.

Original language	English
Pages (from-to)	1013-1016
Journal	Science
Volume	359
Issue number	6379
DOIs	https://doi.org/10.1126/science.aaq1221
Publication status	Published - 2 Mar 2018

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title = "Ideal Weyl points and helicoid surface states in artificial photonic crystal structures",

abstract = "Weyl points are the crossings of linearly dispersing energy bands of three-dimensional crystals, providing the opportunity to explore a variety of intriguing phenomena such as topologically protected surface states and chiral anomalies. However, the lack of an ideal Weyl system in which the Weyl points all exist at the same energy and are separated from any other bands poses a serious limitation to the further development of Weyl physics and potential applications. By experimentally characterizing a microwave photonic crystal of saddle-shaped metallic coils, we observed ideal Weyl points that are related to each other through symmetry operations. Topological surface states exhibiting helicoidal structure have also been demonstrated. Our system provides a photonic platform for exploring ideal Weyl systems and developing possible topological devices.",

author = "Biao Yang and Qinghua Guo and Ben Tremain and Rongjuan Liu and Barr, {Lauren E.} and Qinghui Yan and Wenlong Gao and Hongchao Liu and Yuanjiang Xiang and Jing Cheng and Chen Fang and Alastair Hibbins and Ling Lu and Shuang Zhang",

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TY - JOUR

T1 - Ideal Weyl points and helicoid surface states in artificial photonic crystal structures

AU - Yang, Biao

AU - Guo, Qinghua

AU - Tremain, Ben

AU - Liu, Rongjuan

AU - Barr, Lauren E.

AU - Yan, Qinghui

AU - Gao, Wenlong

AU - Liu, Hongchao

AU - Xiang, Yuanjiang

AU - Cheng, Jing

AU - Fang, Chen

AU - Hibbins, Alastair

AU - Lu, Ling

AU - Zhang, Shuang

PY - 2018/3/2

Y1 - 2018/3/2

N2 - Weyl points are the crossings of linearly dispersing energy bands of three-dimensional crystals, providing the opportunity to explore a variety of intriguing phenomena such as topologically protected surface states and chiral anomalies. However, the lack of an ideal Weyl system in which the Weyl points all exist at the same energy and are separated from any other bands poses a serious limitation to the further development of Weyl physics and potential applications. By experimentally characterizing a microwave photonic crystal of saddle-shaped metallic coils, we observed ideal Weyl points that are related to each other through symmetry operations. Topological surface states exhibiting helicoidal structure have also been demonstrated. Our system provides a photonic platform for exploring ideal Weyl systems and developing possible topological devices.

AB - Weyl points are the crossings of linearly dispersing energy bands of three-dimensional crystals, providing the opportunity to explore a variety of intriguing phenomena such as topologically protected surface states and chiral anomalies. However, the lack of an ideal Weyl system in which the Weyl points all exist at the same energy and are separated from any other bands poses a serious limitation to the further development of Weyl physics and potential applications. By experimentally characterizing a microwave photonic crystal of saddle-shaped metallic coils, we observed ideal Weyl points that are related to each other through symmetry operations. Topological surface states exhibiting helicoidal structure have also been demonstrated. Our system provides a photonic platform for exploring ideal Weyl systems and developing possible topological devices.

U2 - 10.1126/science.aaq1221

DO - 10.1126/science.aaq1221

M3 - Article

SN - 0036-8075

VL - 359

SP - 1013

EP - 1016

JO - Science

JF - Science

IS - 6379

ER -

Ideal Weyl points and helicoid surface states in artificial photonic crystal structures

Abstract

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