Your search keyword '"non-Hermitian optics"' showing total 9 results

1. Optical waveguide power splitter with adjustable splitting ratio using non-Hermitian shortcuts to adiabaticity.

Author

Feng, Yu-xin, Wu, Jin-lei, Ren, Bin, Han, Jin-xuan, Tang, Shuai, Song, Jie, and Jiang, Yong-yuan

Subjects

*INTEGRATED optics, *OPTICAL devices, *WAVEGUIDES

Abstract

Versatile optical devices with smaller space footprint are crucial for integrated optics. In this work, we design a dual-waveguide power splitter with adjustable splitting ratio depending on the input ports. The modulated gain and loss are imposed on two waveguides to nullify the non-adiabatic coupling using non-Hermitian shortcut to adiabaticity technique. Simulation results reveal that the length of the power splitter can be shortened to about one ninth compared to the one along the adiabatic path, meanwhile, the proposed splitter has good robustness against possible fabrication errors. [ABSTRACT FROM AUTHOR]

Published

2023

2. Strategy for Low‐Loss Optical Devices When Using High‐Loss Materials

Author

Yanxian Wei, Junwei Cheng, Yilun Wang, Hailong Zhou, Jianji Dong, Dongmei Huang, Feng Li, Ming Li, Ping Kong Alexander Wai, and Xinliang Zhang

Subjects

integrated optical devices, non-Hermitian optics, optical loss, Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467

Abstract

Material loss, especially in metal and 2D materials, is the bottleneck for high‐performance integrated optical devices. Here, a novel concept by utilizing the high‐loss materials in a non‐Hermitian system instead of avoiding the loss materials. It is theoretically analyzed how the complex refractive index affects the loss of optical devices based on a two‐waveguide‐coupled non‐Hermitian system. The results reveal that the loss of optical devices can be improved by increasing the loss of materials or the difference in real refractive indexes. It is experimentally verified that a high loss material can be placed close to the optical waveguide without introducing non‐negligible loss to the optical devices, by demonstrating a thermo‐optic phase shifter with a metallic heater placed very close to the silicon waveguide. As a result, the insertion loss is only 0.1 dB for the 100 μm long heater with a gap of 400 nm, and the largest bandwidth for the metallic heater reaches up to 280 kHz. The finding offers a way to realize high‐performance optical devices with high‐loss materials, contributing to the practical applications of strongly absorbing materials based on non‐Hermitian optics.

Published

2022

3. Fundamentals and Applications of Topological Polarization Singularities

Author

Feifan Wang, Xuefan Yin, Zixuan Zhang, Zihao Chen, Haoran Wang, Peishen Li, Yuefeng Hu, Xinyi Zhou, and Chao Peng

Subjects

topological charges, topological photonics, bound states in the continuum, optical singularities, non-Hermitian optics, Physics, QC1-999

Abstract

Radiations towards the continuum not only brings non-Hermicity to photonic systems but also provides observable channels for understanding their intrinsic physics underneath. In this article, we review the fundamental physics and applications of topological polarization singularities, which are defined upon the far-field radiation of photonic systems and characterized by topological charges as the winding numbers of polarization orientation around a given center. A brief summarizing of topological charge theory is presented. A series of applications related to topological polarization singularities are then discussed.

Published

2022

4. Hermitian and Non-Hermitian Dirac-Like Cones in Photonic and Phononic Structures

Author

Jie Luo and Yun Lai

Subjects

zero refractive index, photonic/phononic band structure, metamaterials, Dirac/Dirac-like cones, non-Hermitian optics, Physics, QC1-999

Abstract

Accidental degeneracy plays an important role in the generation of novel band dispersions. Photonic structures that exhibit an accidental Dirac-like conical dispersion at the center of the Brillouin zone can behave like a zero-index material at the Dirac-point frequency, leading to a number of unique features, such as invariant phase in space, wave tunneling, photonic doping and anti-doping, etc. Such a phenomenon has been explored in on-chip structures or three dimensions recently. The introduction of non-Hermiticity into the system via loss or gain could transform the accidental Dirac-like cone into a spawning ring of exceptional points, a complex Dirac-like cone or other unique dispersions. Similar Dirac-like cones and related physics are also observed in phononic structures. This review presents an overview of the accidental-degeneracy-induced Dirac-like cones at the center of the Brillouin zone in both photonic and phononic structures, including the fundamental physics, effective-medium description and experimental demonstration, as well as current challenges and future directions.

Published

2022

5. Non-Hermitian doping of epsilon-near-zero media.

Author

Coppolaro, Marino, Moccia, Massimo, Castaldi, Giuseppe, Engheta, Nader, and Galdi, Vincenzo

Subjects

*SEMICONDUCTOR materials, *SOLID state physics, *OPTICAL pumping, *OPTICAL materials, *PERMITTIVITY

Abstract

In solid-state physics, "doping" is a pivotal concept that allows controlling and engineering of the macroscopic electronic and optical properties of materials such as semiconductors by judiciously introducing small concentrations of impurities. Recently, this concept has been translated to two-dimensional photonic scenarios in connection with host media characterized by vanishingly small relative permittivity ("epsilon near zero"), showing that it is possible to obtain broadly tunable effective magnetic responses by introducing a single, nonmagnetic doping particle at an arbitrary position. So far, this phenomenon has been studied mostly for lossless configurations. In principle, the inevitable presence of material losses can be compensated via optical gain. However, taking inspiration from quantum (e.g., parity-time) symmetries that are eliciting growing attention in the emerging fields of non-Hermitian optics and photonics, this suggests considering more general gain-loss interactions. Here, we theoretically show that the photonic doping concept can be extended to non-Hermitian scenarios characterized by tailored distributions of gain and loss in either the doping particles or the host medium. In these scenarios, the effective permeability can be modeled as a complex-valued quantity (with the imaginary part accounting for the gain or loss), which can be tailored over broad regions of the complex plane. This enables a variety of unconventional optical responses and waveguiding mechanisms, which can be, in principle, reconfigured by varying the optical gain (e.g., via optical pumping). We envision several possible applications of this concept, including reconfigurable nanophotonics platforms and optical sensing, which motivate further studies for their experimental validation. [ABSTRACT FROM AUTHOR]

Published

2020

6. Extended SSH Model in Non-Hermitian Waveguides with Alternating Real and Imaginary Couplings.

Author

Fu, Ziwei, Fu, Nianzu, Zhang, Huaiyuan, Wang, Zhe, Zhao, Dong, and Ke, Shaolin

Subjects

ABSOLUTE value, TOPOLOGICAL property, OPTICAL switches, CHIRALITY of nuclear particles, WAVEGUIDES, PHASE transitions

Abstract

We studied the topological properties of an extended Su–Schrieffer–Heeger (SSH) model composed of a binary waveguide array with alternating real and imaginary couplings. The topological invariant of the periodic structures remained quantized with chiral symmetry even though the system was non-Hermitian. The numerical results indicated that phase transition arose when the absolute values of the two couplings were equal. The system supported a topological zero mode at the boundary of nontrivial structures when chiral symmetry was preserved. By adding onsite gain and loss to break chiral symmetry, the topological modes dominated in all supermodes with maximum absolute value of imaginary energy. This study enriches research on the SSH model in non-Hermitian systems and may find applications in optical routers and switches. [ABSTRACT FROM AUTHOR]

Published

2020

7. Extended SSH Model in Non-Hermitian Waveguides with Alternating Real and Imaginary Couplings

Author

Ziwei Fu, Nianzu Fu, Huaiyuan Zhang, Zhe Wang, Dong Zhao, and Shaolin Ke

Subjects

topological phase, waveguides, non-Hermitian optics, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

We studied the topological properties of an extended Su–Schrieffer–Heeger (SSH) model composed of a binary waveguide array with alternating real and imaginary couplings. The topological invariant of the periodic structures remained quantized with chiral symmetry even though the system was non-Hermitian. The numerical results indicated that phase transition arose when the absolute values of the two couplings were equal. The system supported a topological zero mode at the boundary of nontrivial structures when chiral symmetry was preserved. By adding onsite gain and loss to break chiral symmetry, the topological modes dominated in all supermodes with maximum absolute value of imaginary energy. This study enriches research on the SSH model in non-Hermitian systems and may find applications in optical routers and switches.

Published

2020

8. Towards a feasible non-Hermitian light management

Author

W. W. Ahmed, Kestutis Staliunas, Ramon Herrero, Ying Wu, Muriel Botey, Universitat Politècnica de Catalunya. Departament de Física, and Universitat Politècnica de Catalunya. DONLL - Dinàmica no Lineal, Òptica no Lineal i Làsers

Subjects

Física [Àrees temàtiques de la UPC], Computer science, Non-Hermitian optics, Optics, Parameter space, PT-symmetry, Òptica, Topology, Network topology, Hermitian matrix, symbols.namesake, Flow (mathematics), Metamaterials, symbols, Symmetry breaking, Hilbert transform, Focus (optics), Curse of dimensionality

Abstract

Novel physical phenomena arising from the interplay between gain and loss is beyond the recent focus on Non-Hermitian systems. The spatial symmetry breaking in such systems may lead to an arbitrarily control of the flow of light. We present an approach to design Non-Hermitian systems on demand, with desired shapes and topologies based on a modification of the classical Hilbert transform. The procedure allows restricting the dimensionality of the complex index parameter space, keeping the physical properties within practical limits and realizable with a finite collection of materials. Objectius de Desenvolupament Sostenible::9 - Indústria, Innovació i Infraestructura

Published

2020

9. Management of Light Patterns Based on Local Hilbert Transform

Author

Muriel Botey, W. W. Ahmed, Zeki Hayran, Ramon Herrero, K. Staliunas, Hamza Kurt, Universitat Politècnica de Catalunya. Departament de Física, and Universitat Politècnica de Catalunya. DONLL - Dinàmica no Lineal, Òptica no Lineal i Làsers

Subjects

Physics, Signal processing, Física [Àrees temàtiques de la UPC], Metamaterial, non-Hermitian optics, light patterns, Optical field, Topology, Network topology, 01 natural sciences, Tractament del senyal, 010305 fluids & plasmas, Vortex, symbols.namesake, metamaterials, 0103 physical sciences, symbols, Directionality, Vector field, Hilbert transform, 010306 general physics, Focus (optics)

Abstract

We propose a new approach of optical field management based on a local Hilbert transform, where the non-Hermitian potentials generating arbitrary vector fields of directionality p(\vec r), with desired shapes and topologies are designed. We derive a local Hilbert transform to build systematically such potentials, by modifying background potentials (being either regular or random, extended or localized). In particular, we explore particular directionality fields, for instance in the form of a focus to create sinks for probe fields, to generate vortices in the probe fields, and others. Physically, the proposed directionality fields provide a flexible new mechanism for dynamically shaping and precise control over probe fields leading to novel effects in wave dynamics. © 2018 IEEE.

Published

2018