Nontrivial point-gap topology and non-Hermitian skin effect in photonic crystals

Janet Zhong; Kai Wang; Yubin Park; Viktar Asadchy; Charles C. Wojcik; Avik Dutt; Shanhui Fan

doi:10.1103/PhysRevB.104.125416

Nontrivial point-gap topology and non-Hermitian skin effect in photonic crystals

Janet Zhong, Kai Wang, Yubin Park, Viktar Asadchy, Charles C. Wojcik, Avik Dutt, Shanhui Fan^*

^*Corresponding author for this work

Not published at Aalto University

Stanford University

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

60 Citations (Scopus)

Abstract

We show that two-dimensional non-Hermitian photonic crystals made of lossy material can exhibit nontrivial point-gap topology in terms of topological winding in its complex frequency band structure. Such crystals can be made of either lossy isotropic media which is reciprocal or lossy magneto-optical media which is nonreciprocal. We discuss the effects of reciprocity on the properties of the point-gap topology. We also show that such a nontrivial point-gap topology leads to the non-Hermitian skin effect when the photonic crystal is truncated. In contrast to most previous studies on point-gap topology which used tight-binding models, our work indicates that such non-Hermitian topology can studied in photonic crystals, which represent a more realistic system that has technological significance.

Original language	English
Article number	125416
Journal	Physical Review B
Volume	104
Issue number	12
DOIs	https://doi.org/10.1103/PhysRevB.104.125416
Publication status	Published - 15 Sept 2021
MoE publication type	A1 Journal article-refereed

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10.1103/PhysRevB.104.125416

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abstract = "We show that two-dimensional non-Hermitian photonic crystals made of lossy material can exhibit nontrivial point-gap topology in terms of topological winding in its complex frequency band structure. Such crystals can be made of either lossy isotropic media which is reciprocal or lossy magneto-optical media which is nonreciprocal. We discuss the effects of reciprocity on the properties of the point-gap topology. We also show that such a nontrivial point-gap topology leads to the non-Hermitian skin effect when the photonic crystal is truncated. In contrast to most previous studies on point-gap topology which used tight-binding models, our work indicates that such non-Hermitian topology can studied in photonic crystals, which represent a more realistic system that has technological significance.",

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AU - Wojcik, Charles C.

AU - Dutt, Avik

AU - Fan, Shanhui

N1 - Funding Information: This work is supported by a Vannevar Bush Faculty Fellowship from the U.S. Department of Defense (Grant No. N00014-17-1-3030). J.Z. acknowledges support from the Fulbright Future Scholarship. Publisher Copyright: © 2021 American Physical Society.

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N2 - We show that two-dimensional non-Hermitian photonic crystals made of lossy material can exhibit nontrivial point-gap topology in terms of topological winding in its complex frequency band structure. Such crystals can be made of either lossy isotropic media which is reciprocal or lossy magneto-optical media which is nonreciprocal. We discuss the effects of reciprocity on the properties of the point-gap topology. We also show that such a nontrivial point-gap topology leads to the non-Hermitian skin effect when the photonic crystal is truncated. In contrast to most previous studies on point-gap topology which used tight-binding models, our work indicates that such non-Hermitian topology can studied in photonic crystals, which represent a more realistic system that has technological significance.

AB - We show that two-dimensional non-Hermitian photonic crystals made of lossy material can exhibit nontrivial point-gap topology in terms of topological winding in its complex frequency band structure. Such crystals can be made of either lossy isotropic media which is reciprocal or lossy magneto-optical media which is nonreciprocal. We discuss the effects of reciprocity on the properties of the point-gap topology. We also show that such a nontrivial point-gap topology leads to the non-Hermitian skin effect when the photonic crystal is truncated. In contrast to most previous studies on point-gap topology which used tight-binding models, our work indicates that such non-Hermitian topology can studied in photonic crystals, which represent a more realistic system that has technological significance.

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Nontrivial point-gap topology and non-Hermitian skin effect in photonic crystals

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