Higher‐order topological states in surface‐wave photonic crystals
Photonic topological states have revolutionized the understanding of the propagation and scattering of light. The recent discovery of higher‐order photonic topological insulators opens an emergent horizon for 0D topological corner states. However, the previous realizations of higher‐order topologica...
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sg-ntu-dr.10356-1455762023-02-28T20:03:33Z Higher‐order topological states in surface‐wave photonic crystals Zhang, Li Yang, Yihao Lin, Zhi-Kang Qin, Pengfei Chen, Qiaolu Gao, Fei Li, Erping Jiang, Jian-Hua Zhang, Baile Chen, Hongsheng School of Physical and Mathematical Sciences Centre for Disruptive Photonic Technologies (CDPT) The Photonics Institute Science::Physics Higher Order Photonic Topological Insulators Photonic Crystals Photonic topological states have revolutionized the understanding of the propagation and scattering of light. The recent discovery of higher‐order photonic topological insulators opens an emergent horizon for 0D topological corner states. However, the previous realizations of higher‐order topological insulators in electromagnetic‐wave systems suffer from either a limited operational frequency range due to the lumped components involved or a bulky structure with a large footprint, which are unfavorable for achieving compact photonic devices. To overcome these limitations, a planar surface‐wave photonic crystal realization of 2D higher‐order topological insulators is hereby demonstrated experimentally. The surface‐wave photonic crystals exhibit a very large bulk bandgap (a bandwidth of 28%) due to multiple Bragg scatterings and host 1D gapped edge states described by massive Dirac equations. The topology of those higher‐dimensional photonic bands leads to the emergence of in‐gap 0D corner states, which provide a route toward robust cavity modes for scalable compact photonic devices. Ministry of Education (MOE) Published version L.Z. and Y.Y. contributed equally to this work. This work was sponsored by the National Natural Science Foundation of China under Grants Nos. 61625502, 11961141010, 61975176, and 61801426 and the Jiangsu province distinguished professor funding. Work at Nanyang Technological University was sponsored by Singapore Ministry of Education under Grant Nos. MOE2018‐T2‐1‐022 (S), MOE2015‐T2‐1‐070, MOE2016‐T3‐1‐006, and Tier 1 RG174/16 (S). 2020-12-29T04:10:10Z 2020-12-29T04:10:10Z 2020 Journal Article Zhang, L., Yang, Y., Lin, Z.-K., Qin, P., Chen, Q., Gao, F., . . . Chen, H. (2020). Higher‐order topological states in surface‐wave photonic crystals. Advanced Science, 7(6), 1902724-. doi:10.1002/advs.201902724 2198-3844 https://hdl.handle.net/10356/145576 10.1002/advs.201902724 32195092 6 7 en MOE2018‐T2‐1‐022 (S) MOE2015‐T2‐1‐070 MOE2016‐T3‐1‐006 RG174/16 (S) Advanced Science 10.21979/N9/OZATGF © 2020 The Authors. Published by WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited. application/pdf |
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Science::Physics Higher Order Photonic Topological Insulators Photonic Crystals |
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Science::Physics Higher Order Photonic Topological Insulators Photonic Crystals Zhang, Li Yang, Yihao Lin, Zhi-Kang Qin, Pengfei Chen, Qiaolu Gao, Fei Li, Erping Jiang, Jian-Hua Zhang, Baile Chen, Hongsheng Higher‐order topological states in surface‐wave photonic crystals |
| description |
Photonic topological states have revolutionized the understanding of the propagation and scattering of light. The recent discovery of higher‐order photonic topological insulators opens an emergent horizon for 0D topological corner states. However, the previous realizations of higher‐order topological insulators in electromagnetic‐wave systems suffer from either a limited operational frequency range due to the lumped components involved or a bulky structure with a large footprint, which are unfavorable for achieving compact photonic devices. To overcome these limitations, a planar surface‐wave photonic crystal realization of 2D higher‐order topological insulators is hereby demonstrated experimentally. The surface‐wave photonic crystals exhibit a very large bulk bandgap (a bandwidth of 28%) due to multiple Bragg scatterings and host 1D gapped edge states described by massive Dirac equations. The topology of those higher‐dimensional photonic bands leads to the emergence of in‐gap 0D corner states, which provide a route toward robust cavity modes for scalable compact photonic devices. |
| author2 |
School of Physical and Mathematical Sciences |
| author_facet |
School of Physical and Mathematical Sciences Zhang, Li Yang, Yihao Lin, Zhi-Kang Qin, Pengfei Chen, Qiaolu Gao, Fei Li, Erping Jiang, Jian-Hua Zhang, Baile Chen, Hongsheng |
| format |
Article |
| author |
Zhang, Li Yang, Yihao Lin, Zhi-Kang Qin, Pengfei Chen, Qiaolu Gao, Fei Li, Erping Jiang, Jian-Hua Zhang, Baile Chen, Hongsheng |
| author_sort |
Zhang, Li |
| title |
Higher‐order topological states in surface‐wave photonic crystals |
| title_short |
Higher‐order topological states in surface‐wave photonic crystals |
| title_full |
Higher‐order topological states in surface‐wave photonic crystals |
| title_fullStr |
Higher‐order topological states in surface‐wave photonic crystals |
| title_full_unstemmed |
Higher‐order topological states in surface‐wave photonic crystals |
| title_sort |
higher‐order topological states in surface‐wave photonic crystals |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/145576 |
| _version_ |
1759853066699407360 |