Q-factor optimization of modes in ordered and disordered photonic systems using non-Hermitian perturbation theory
Q-factor optimization of modes in ordered and disordered photonic systems using non-Hermitian perturbation theory
The quality factor, Q, of photonic resonators permeates most figures of merit in applications that rely on cavity-enhanced light-matter interaction such as all-optical information processing, high-resolution sensing, or ultralow-threshold lasing. As a consequence, large-scale efforts have been devoted to understanding and efficiently computing and optimizing the Q of optical resonators in the design stage. This has generated large know-how on the relation between physical quantities of the cavity, e.g., Q, and controllable parameters, e.g., hole positions, for engineered cavities in gaped photonic crystals. However, such a correspondence is much less intuitive in the case of modes in disordered photonic media, e.g., Anderson-localized modes. Here, we demonstrate that the theoretical framework of quasinormal modes (QNMs), a non-Hermitian perturbation theory for shifting material boundaries, and a finite-element complex eigensolver provide an ideal toolbox for the automated shape optimization of Q of a single photonic mode in both ordered and disordered environments. We benchmark the non-Hermitian perturbation formula and employ it to optimize the Q-factor of a photonic mode relative to the position of vertically etched holes in a dielectric slab for two different settings: first, for the fundamental mode of L3 cavities with various footprints, demonstrating that the approach simultaneously takes in-plane and out-of-plane losses into account and leads to minor modal structure modifications; and second, for an Anderson-localized mode with an initial Q of 200, which evolves into a completely different mode, displaying a threefold reduction in the mode volume, a different overall spatial location, and, notably, a 3 order of magnitude increase in Q.
Anderson modes, Q-factor optimization, non-Hermitian perturbation theory, photonic resonators, quasinormal modes, random systems
2808-2815
Granchi, Nicoletta
7dd88394-bc32-4366-928d-14a8b75a9dc1
Intonti, Francesca
3eaf0e93-e2f7-4644-a279-b6b86ce52a4a
Florescu, Marian
14b7415d-9dc6-4ebe-a125-289e47648c65
García, Pedro David
c643b2a6-412f-4b97-b204-c284626ccd91
Gurioli, Massimo
7c8a8ce0-3765-488b-baa7-174428ede2b7
Arregui, Guillermo
287597a2-5b15-49fa-aec5-4c0ac44395f5
16 August 2023
Granchi, Nicoletta
7dd88394-bc32-4366-928d-14a8b75a9dc1
Intonti, Francesca
3eaf0e93-e2f7-4644-a279-b6b86ce52a4a
Florescu, Marian
14b7415d-9dc6-4ebe-a125-289e47648c65
García, Pedro David
c643b2a6-412f-4b97-b204-c284626ccd91
Gurioli, Massimo
7c8a8ce0-3765-488b-baa7-174428ede2b7
Arregui, Guillermo
287597a2-5b15-49fa-aec5-4c0ac44395f5
Granchi, Nicoletta, Intonti, Francesca, Florescu, Marian, García, Pedro David, Gurioli, Massimo and Arregui, Guillermo
(2023)
Q-factor optimization of modes in ordered and disordered photonic systems using non-Hermitian perturbation theory.
ACS Photonics, 10 (8), .
(doi:10.1021/acsphotonics.3c00510).
Abstract
The quality factor, Q, of photonic resonators permeates most figures of merit in applications that rely on cavity-enhanced light-matter interaction such as all-optical information processing, high-resolution sensing, or ultralow-threshold lasing. As a consequence, large-scale efforts have been devoted to understanding and efficiently computing and optimizing the Q of optical resonators in the design stage. This has generated large know-how on the relation between physical quantities of the cavity, e.g., Q, and controllable parameters, e.g., hole positions, for engineered cavities in gaped photonic crystals. However, such a correspondence is much less intuitive in the case of modes in disordered photonic media, e.g., Anderson-localized modes. Here, we demonstrate that the theoretical framework of quasinormal modes (QNMs), a non-Hermitian perturbation theory for shifting material boundaries, and a finite-element complex eigensolver provide an ideal toolbox for the automated shape optimization of Q of a single photonic mode in both ordered and disordered environments. We benchmark the non-Hermitian perturbation formula and employ it to optimize the Q-factor of a photonic mode relative to the position of vertically etched holes in a dielectric slab for two different settings: first, for the fundamental mode of L3 cavities with various footprints, demonstrating that the approach simultaneously takes in-plane and out-of-plane losses into account and leads to minor modal structure modifications; and second, for an Anderson-localized mode with an initial Q of 200, which evolves into a completely different mode, displaying a threefold reduction in the mode volume, a different overall spatial location, and, notably, a 3 order of magnitude increase in Q.
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granchi-et-al-2023-q-factor-optimization-of-modes-in-ordered-and-disordered-photonic-systems-using-non-hermitian
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More information
e-pub ahead of print date: 10 July 2023
Published date: 16 August 2023
Additional Information:
A correction to this research output can be found at: https://doi.org/10.1021/acsphotonics.4c00229
Keywords:
Anderson modes, Q-factor optimization, non-Hermitian perturbation theory, photonic resonators, quasinormal modes, random systems
Identifiers
Local EPrints ID: 502884
URI: http://eprints.soton.ac.uk/id/eprint/502884
ISSN: 2330-4022
PURE UUID: 766173d2-a426-4046-af8b-62f23497331b
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Date deposited: 10 Jul 2025 17:24
Last modified: 22 Aug 2025 02:46
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Contributors
Author:
Nicoletta Granchi
Author:
Francesca Intonti
Author:
Marian Florescu
Author:
Pedro David García
Author:
Massimo Gurioli
Author:
Guillermo Arregui
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