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Realization of a three-dimensional photonic topological insulator

Author

Listed:
  • Yihao Yang

    (The Electromagnetics Academy at Zhejiang University, Zhejiang University
    Zhejiang University
    Nanyang Technological University
    Nanyang Technological University)

  • Zhen Gao

    (Nanyang Technological University
    Nanyang Technological University)

  • Haoran Xue

    (Nanyang Technological University
    Nanyang Technological University)

  • Li Zhang

    (The Electromagnetics Academy at Zhejiang University, Zhejiang University
    Zhejiang University)

  • Mengjia He

    (The Electromagnetics Academy at Zhejiang University, Zhejiang University
    Zhejiang University)

  • Zhaoju Yang

    (Nanyang Technological University
    Nanyang Technological University)

  • Ranjan Singh

    (Nanyang Technological University
    Nanyang Technological University)

  • Yidong Chong

    (Nanyang Technological University
    Nanyang Technological University)

  • Baile Zhang

    (Nanyang Technological University
    Nanyang Technological University)

  • Hongsheng Chen

    (The Electromagnetics Academy at Zhejiang University, Zhejiang University
    Zhejiang University)

Abstract

Confining photons in a finite volume is highly desirable in modern photonic devices, such as waveguides, lasers and cavities. Decades ago, this motivated the study and application of photonic crystals, which have a photonic bandgap that forbids light propagation in all directions1–3. Recently, inspired by the discoveries of topological insulators4,5, the confinement of photons with topological protection has been demonstrated in two-dimensional (2D) photonic structures known as photonic topological insulators6–8, with promising applications in topological lasers9,10 and robust optical delay lines11. However, a fully three-dimensional (3D) topological photonic bandgap has not been achieved. Here we experimentally demonstrate a 3D photonic topological insulator with an extremely wide (more than 25 per cent bandwidth) 3D topological bandgap. The composite material (metallic patterns on printed circuit boards) consists of split-ring resonators (classical electromagnetic artificial atoms) with strong magneto-electric coupling and behaves like a ‘weak’ topological insulator (that is, with an even number of surface Dirac cones), or a stack of 2D quantum spin Hall insulators. Using direct field measurements, we map out both the gapped bulk band structure and the Dirac-like dispersion of the photonic surface states, and demonstrate robust photonic propagation along a non-planar surface. Our work extends the family of 3D topological insulators from fermions to bosons and paves the way for applications in topological photonic cavities, circuits and lasers in 3D geometries.

Suggested Citation

  • Yihao Yang & Zhen Gao & Haoran Xue & Li Zhang & Mengjia He & Zhaoju Yang & Ranjan Singh & Yidong Chong & Baile Zhang & Hongsheng Chen, 2019. "Realization of a three-dimensional photonic topological insulator," Nature, Nature, vol. 565(7741), pages 622-626, January.
    • Handle: RePEc:nat:nature:v:565:y:2019:i:7741:d:10.1038_s41586-018-0829-0
    DOI: 10.1038/s41586-018-0829-0
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    Citations

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    Cited by:

    1. Guoqiang Xu & Xue Zhou & Shuihua Yang & Jing Wu & Cheng-Wei Qiu, 2023. "Observation of bulk quadrupole in topological heat transport," Nature Communications, Nature, vol. 14(1), pages 1-9, December.
    2. Minkyung Kim & Zihao Wang & Yihao Yang & Hau Tian Teo & Junsuk Rho & Baile Zhang, 2022. "Three-dimensional photonic topological insulator without spin–orbit coupling," Nature Communications, Nature, vol. 13(1), pages 1-7, December.
    3. Junhong Liu & Yunfei Xu & Rusong Li & Yongqiang Sun & Kaiyao Xin & Jinchuan Zhang & Quanyong Lu & Ning Zhuo & Junqi Liu & Lijun Wang & Fengmin Cheng & Shuman Liu & Fengqi Liu & Shenqiang Zhai, 2024. "High-power electrically pumped terahertz topological laser based on a surface metallic Dirac-vortex cavity," Nature Communications, Nature, vol. 15(1), pages 1-7, December.
    4. Jingyi Tian & Qi Ying Tan & Yutao Wang & Yihao Yang & Guanghui Yuan & Giorgio Adamo & Cesare Soci, 2023. "Perovskite quantum dot one-dimensional topological laser," Nature Communications, Nature, vol. 14(1), pages 1-7, December.
    5. Lei Huang & Lu He & Weixuan Zhang & Huizhen Zhang & Dongning Liu & Xue Feng & Fang Liu & Kaiyu Cui & Yidong Huang & Wei Zhang & Xiangdong Zhang, 2024. "Hyperbolic photonic topological insulators," Nature Communications, Nature, vol. 15(1), pages 1-9, December.
    6. Xiaoxiao Wu & Haiyan Fan & Tuo Liu & Zhongming Gu & Ruo-Yang Zhang & Jie Zhu & Xiang Zhang, 2022. "Topological phononics arising from fluid-solid interactions," Nature Communications, Nature, vol. 13(1), pages 1-7, December.
    7. Ren, Boquan & Kartashov, Yaroslav V. & Wang, Hongguang & Li, Yongdong & Zhang, Yiqi, 2023. "Floquet topological insulators with hybrid edges," Chaos, Solitons & Fractals, Elsevier, vol. 166(C).
    8. Weitao Yuan & Chenwen Yang & Danmei Zhang & Yang Long & Yongdong Pan & Zheng Zhong & Hong Chen & Jinfeng Zhao & Jie Ren, 2021. "Observation of elastic spin with chiral meta-sources," Nature Communications, Nature, vol. 12(1), pages 1-9, December.

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