Near‐Field Characterization of Higher‐Order Topological Photonic States at Optical Frequencies

Vakulenko, Anton; Kiriushechkina, Svetlana; Wang, Mingsong; Li, Mengyao; Zhirihin, Dmitry; Ni, Xiang; Guddala, Sriram; Korobkin, Dmitry; Alù, Andrea; Khanikaev, Alexander B.

doi:10.1002/adma.202004376

Near‐Field Characterization of Higher‐Order Topological Photonic States at Optical Frequencies

Journal Article · Thu Mar 18 00:00:00 EDT 2021 · Advanced Materials

DOI:https://doi.org/10.1002/adma.202004376· OSTI ID:1804231

Vakulenko, Anton ^[1]; Kiriushechkina, Svetlana ^[1]; Wang, Mingsong ^[2]; Li, Mengyao ^[3]; Zhirihin, Dmitry ^[4]; Ni, Xiang ^[5]; Guddala, Sriram ^[1]; Korobkin, Dmitry ^[2]; Alù, Andrea ^[5]; ^[3]

Department of Electrical Engineering Grove School of Engineering City College of the City University of New York 140th Street and Convent Avenue New York NY 10031 USA
Photonics Initiative Advanced Science Research Center City University of New York New York NY 10031 USA
Department of Electrical Engineering Grove School of Engineering City College of the City University of New York 140th Street and Convent Avenue New York NY 10031 USA, Physics Program Graduate Center of the City University of New York New York NY 10016 USA
Department of Physics and Engineering ITMO University Saint Petersburg 197101 Russia
Department of Electrical Engineering Grove School of Engineering City College of the City University of New York 140th Street and Convent Avenue New York NY 10031 USA, Photonics Initiative Advanced Science Research Center City University of New York New York NY 10031 USA, Physics Program Graduate Center of the City University of New York New York NY 10016 USA

Abstract

Higher‐order topological insulators (HOTIs) represent a new type of topological system, supporting boundary states localized over boundaries, two or more dimensions lower than the dimensionality of the system itself. Interestingly, photonic HOTIs can possess a richer physics than their original condensed matter counterpart, supporting conventional HOTI states based on tight‐binding coupling, and a new type of topological HOTI states enabled by long‐range interactions. Here, a new mechanism to establish all‐dielectric infrared HOTI metasurfaces exhibiting both types of HOTI states is proposed, supported by a topological transition accompanied by the emergence of topological Wannier‐type polarization. Two kinds of near‐field experimental studies are performed: i) the solid immersion spectroscopy and ii) near‐field imaging using scattering scanning near‐field optical microscopy to directly observe the topological transition and the emergence of HOTI states of two types. It is shown that the near‐field profiles indicate the displacement of the Wannier center across the topological transition leading to the topological dipole polarization and emergence of the topological boundary states. The proposed all‐dielectric HOTI metasurface offers a new approach to confine the optical field in micro‐ and nano‐scale topological cavities and thus paves the way to achieve a novel nanophotonic technology.

View Accepted Manuscript (Publisher)

Sponsoring Organization:: USDOE

OSTI ID:: 1804231

Journal Information:: Advanced Materials, Journal Name: Advanced Materials Journal Issue: 18 Vol. 33; ISSN 0935-9648

Publisher:: Wiley Blackwell (John Wiley & Sons)Copyright Statement

Country of Publication:: Germany

Language:: English

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