Time-asymmetric loop around an exceptional point over the full optical communications band
- Authors
- Yoon, jae woong; Choi, Youngsun; Hahn, Choloong; Kim, Gunpyo; Song, Seok Ho; Yang, Ki-Yeon; Lee, Jeong Yub; Kim, Yongsung; Lee, Chang Seung; Shin, Jai Kwang; Lee, Hong-Seok; Berini, Pierre
- Issue Date
- Oct-2018
- Publisher
- Nature Publishing Group
- Citation
- Nature, v.562, no.7725, pp 86 - 90
- Pages
- 5
- Indexed
- SCI
SCIE
SCOPUS
- Journal Title
- Nature
- Volume
- 562
- Number
- 7725
- Start Page
- 86
- End Page
- 90
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/149273
- DOI
- 10.1038/s41586-018-0523-2
- ISSN
- 0028-0836
1476-4687
- Abstract
- Topological operations around exceptional points(1-8)-time-varying system configurations associated with non-Hermitian singularities-have been proposed as a robust approach to achieving far-reaching open-system dynamics, as demonstrated in highly dissipative microwave transmission(3) and cryogenic optomechanical oscillator(4) experiments. In stark contrast to conventional systems based on closed-system Hermitian dynamics, environmental interferences at exceptional points are dynamically engaged with their internal coupling properties to create rotational stimuli in fictitious-parameter domains, resulting in chiral systems that exhibit various anomalous physical phenomena(9-16). To achieve new wave properties and concomitant device architectures to control them, realizations of such systems in application-abundant technological areas, including communications and signal processing systems, are the next step. However, it is currently unclear whether non-Hermitian interaction schemes can be configured in robust technological platforms for further device engineering. Here we experimentally demonstrate a robust silicon photonic structure with photonic modes that transmit through time-asymmetric loops around an exceptional point in the optical domain. The proposed structure consists of two coupled silicon-channel waveguides and a slab-waveguide leakage-radiation sink that precisely control the required non-Hermitian Hamiltonian experienced by the photonic modes. The fabricated devices generate time-asymmetric light transmission over an extremely broad spectral band covering the entire optical telecommunications window (wavelengths between 1.26 and 1.675 micrometres). Thus, we take a step towards broadband on-chip optical devices based on non-Hermitian topological dynamics by using a semiconductor platform with controllable optoelectronic properties, and towards several potential practical applications, such as on-chip optical isolators and non-reciprocal mode converters. Our results further suggest the technological relevance of non-Hermitian wave dynamics in various other branches of physics, such as acoustics, condensed-matter physics and quantum mechanics.
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