Isotropic gap formation, localization, and waveguiding in mesoscale Yukawa-potential amorphous structures

Amorphous photonic structures are mesoscopic optical structures described by electrical permittivity distributions with underlying spatial randomness. They offer a unique platform for studying a broad set of electromagnetic phenomena, including transverse Anderson localization, enhanced wave transpo...

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Published inCommunications physics Vol. 7; no. 1; pp. 45 - 8
Main Authors Sarihan, Murat Can, Govdeli, Alperen, Lan, Zhihao, Yilmaz, Yildirim Batuhan, Erdil, Mertcan, Wang, Yupei, Aras, Mehmet Sirin, Yanik, Cenk, Panoiu, Nicolae Coriolan, Wong, Chee Wei, Kocaman, Serdar
Format Journal Article
LanguageEnglish
Published London Nature Publishing Group UK 31.01.2024
Nature Publishing Group
Nature Portfolio
Subjects
639/624
639/766/400
Amorphous semiconductors
Amorphous structure
Anderson localization
Asymmetry
Carrier transport
Energy gap
First principles
Localization
Nanotechnology devices
Photonics
Physics
Physics and Astronomy
Planar structures
Transport phenomena
Waveguides
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Summary:Amorphous photonic structures are mesoscopic optical structures described by electrical permittivity distributions with underlying spatial randomness. They offer a unique platform for studying a broad set of electromagnetic phenomena, including transverse Anderson localization, enhanced wave transport, and suppressed diffusion in random media. Despite this, at a more practical level, there is insufficient work on both understanding the nature of optical transport and the conditions conducive to vector-wave localization in these planar structures, as well as their potential applications to photonic nanodevices. In this study, we fill this gap by investigating experimentally and theoretically the characteristics of optical transport in a class of amorphous photonic structures and by demonstrating their use to some basic waveguiding nanostructures. We demonstrate that these 2-D structures have unique isotropic and asymmetric band gaps for in-plane propagation, controlled from first principles by varying the scattering strength and whose properties are elucidated by establishing an analogy between photon and carrier transport in amorphous semiconductors. We further observe Urbach band tails in these random structures and uncover their relation to frequency- and disorder-dependent Anderson-like localized modes through the modified Ioffe-Regel criterion and their mean free path - localization length character. Finally, we illustrate that our amorphous structures can serve as a versatile platform in which photonic devices such as disorder-localized waveguides can be readily implemented. Editors Summary: Amorphous photonic structures offer a unique platform for studying unique optical transport phenomena in random media. The authors examine both experimentally and theoretically TE (in-plane) polarized near-infrared light in amorphous structures, demonstrating isotropic and asymmetric bandgaps, Anderson-like localized states at the midgap, and readily available practical waveguide structures.
ISSN:2399-3650
2399-3650
DOI:10.1038/s42005-023-01482-9