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Main Authors: You, Yue, Du, Xiao-Jing, Ma, Lin, Qiu, Hua, He, Jun, Yang, Zhong-Jian
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2503.12311
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author You, Yue
Du, Xiao-Jing
Ma, Lin
Qiu, Hua
He, Jun
Yang, Zhong-Jian
author_facet You, Yue
Du, Xiao-Jing
Ma, Lin
Qiu, Hua
He, Jun
Yang, Zhong-Jian
contents As for plasmonic antenna structures that generate localized near-field enhancement, the most effective current implementations are based on electric dipole resonance modes, but this approach also imposes limitations on their further optimization. Here we introduce an ASRR structure whose ASR mode enables differential charge distribution across both sides of the split. Through asymmetric regulation, charges at one end can become highly localized, thereby achieving efficient near-field enhancement. The formation of this structure was initially driven by a hybrid computational framework integrating evolutionary optimization with residual neural networks, and subsequently simplified into an ASRR prototype using the Occam's Razor principle. The ASRR dimer structure can achieve an electric field intensity enhancement over 6.5 times larger than a traditional nanorod dimer, while maintaining a compact size (<1/3 the working wavelength). The ASRR configuration also demonstrates superior Purcell factor and fluorescence enhancement. These results can find applications in surface-enhanced spectroscopy, nonlinear optics, and quantum light-matter interactions.
format Preprint
id arxiv_https___arxiv_org_abs_2503_12311
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Subwavelength plasmonic antennas based on asymmetric split-ring-resonators for high near-field enhancements
You, Yue
Du, Xiao-Jing
Ma, Lin
Qiu, Hua
He, Jun
Yang, Zhong-Jian
Optics
As for plasmonic antenna structures that generate localized near-field enhancement, the most effective current implementations are based on electric dipole resonance modes, but this approach also imposes limitations on their further optimization. Here we introduce an ASRR structure whose ASR mode enables differential charge distribution across both sides of the split. Through asymmetric regulation, charges at one end can become highly localized, thereby achieving efficient near-field enhancement. The formation of this structure was initially driven by a hybrid computational framework integrating evolutionary optimization with residual neural networks, and subsequently simplified into an ASRR prototype using the Occam's Razor principle. The ASRR dimer structure can achieve an electric field intensity enhancement over 6.5 times larger than a traditional nanorod dimer, while maintaining a compact size (<1/3 the working wavelength). The ASRR configuration also demonstrates superior Purcell factor and fluorescence enhancement. These results can find applications in surface-enhanced spectroscopy, nonlinear optics, and quantum light-matter interactions.
title Subwavelength plasmonic antennas based on asymmetric split-ring-resonators for high near-field enhancements
topic Optics
url https://arxiv.org/abs/2503.12311