Line-wave Waveguide Engineering Using Hermitian and Non-Hermitian Metasurfaces

Overview

Journal Sci Rep

Specialty Science

Date 2024 Mar 8

PMID 38459080

Authors

Haddi Ahmadi

Zahra Ahmadi

Nasrin Razmjooei

Mohammad Pasdari-Kia

Amirmasood Bagheri

Hamed Saghaei

Kamalodin Arik

Homayoon Oraizi

Affiliations

Soon will be listed here.

Abstract

Line waves (LWs) refer to confined edge modes that propagate along the interface of dual electromagnetic metasurfaces while maintaining mirror reflection symmetries. Previous research has both theoretically and experimentally investigated these waves, revealing their presence in the microwave and terahertz frequency ranges. In addition, a comprehensive exploration has been conducted on the implementation of non-Hermitian LWs by establishing the parity-time symmetry. This study introduces a cutting-edge dual-band line-wave waveguide, enabling the realization of LWs within the terahertz and infrared spectrums. Our work is centered around analyzing the functionalities of existing applications of LWs within a specific field. In addition, a novel non-Hermitian platform is proposed. We address feasible practical implementations of non-Hermitian LWs by placing a graphene-based metasurface on an epsilon-near-zero material. This study delves into the advantages of the proposed framework compared to previously examined structures, involving both analytical and numerical examinations of how these waves propagate and the underlying physical mechanisms.

Citing Articles

Self-reactive impedance surfaces for enhanced quasi-line wave propagation in the terahertz spectrum.

Ahmadi Z, Saghaei H, Pasdari-Kia M, Ahmadi H, Razmjooei N, Ghoreishi F Sci Rep. 2025; 15(1):6033.

PMID: 39972016 PMC: 11840005. DOI: 10.1038/s41598-025-90517-y.

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