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Autori principali: Shubitidze, Tornike, Zhu, Yilin, Sundar, Hari, Negro, Luca Dal
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2401.15244
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author Shubitidze, Tornike
Zhu, Yilin
Sundar, Hari
Negro, Luca Dal
author_facet Shubitidze, Tornike
Zhu, Yilin
Sundar, Hari
Negro, Luca Dal
contents In this paper, we investigate the localization properties of optical waves in disordered systems with multifractal scattering potentials. In particular, we apply the localization landscape theory to the classical Helmholtz operator and, without solving the associated eigenproblem, show accurate predictions of localized eigenmodes for one- and two-dimensional multifractal structures. Finally, we design and fabricate nanoperforated photonic membranes in silicon nitride (SiN) and image directly their multifractal modes using leaky-mode spectroscopy in the visible spectral range. The measured data demonstrate optical resonances with multiscale intensity fluctuations in good qualitative agreement with numerical simulations. The proposed approach provides a convenient strategy to design multifractal photonic membranes, enabling rapid exploration of extended scattering structures with tailored disorder for enhanced light-matter interactions.
format Preprint
id arxiv_https___arxiv_org_abs_2401_15244
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Localization landscape of optical waves in multifractal photonic membranes
Shubitidze, Tornike
Zhu, Yilin
Sundar, Hari
Negro, Luca Dal
Optics
In this paper, we investigate the localization properties of optical waves in disordered systems with multifractal scattering potentials. In particular, we apply the localization landscape theory to the classical Helmholtz operator and, without solving the associated eigenproblem, show accurate predictions of localized eigenmodes for one- and two-dimensional multifractal structures. Finally, we design and fabricate nanoperforated photonic membranes in silicon nitride (SiN) and image directly their multifractal modes using leaky-mode spectroscopy in the visible spectral range. The measured data demonstrate optical resonances with multiscale intensity fluctuations in good qualitative agreement with numerical simulations. The proposed approach provides a convenient strategy to design multifractal photonic membranes, enabling rapid exploration of extended scattering structures with tailored disorder for enhanced light-matter interactions.
title Localization landscape of optical waves in multifractal photonic membranes
topic Optics
url https://arxiv.org/abs/2401.15244