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Autores principales: Yang, Qianru, Wu, Haotian, Hu, Hao, García-Vidal, F. J., Hu, Guangwei, Luo, Yu
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2411.08157
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author Yang, Qianru
Wu, Haotian
Hu, Hao
García-Vidal, F. J.
Hu, Guangwei
Luo, Yu
author_facet Yang, Qianru
Wu, Haotian
Hu, Hao
García-Vidal, F. J.
Hu, Guangwei
Luo, Yu
contents Superfocusing confines light within subwavelength structures, breaking the diffraction limit. Structures with spatial singularities, such as metallic cones, are crucial to enable nanoscale focusing, leading to significant advancements in nanophotonics, sensing, and imaging. Here, we exploit the spatiotemporal analogue of the wedge structure, i.e. a dielectric medium sandwiched between two subluminal interfaces with distinct velocities, to focus propagating waves beyond the diffraction limit, achieving spatiotemporal superfocusing. Within this structure, an incident pulse undergoes continuous spatial and temporal compression due to Doppler effects, which accumulates and results in an extreme focusing as it approaches the spatiotemporal vertex. Remarkably, unlike the field localization in conventional superfocusing, the compressed light in spatiotemporal wedges experiences significant amplification and then couple to the far field in free space. Our findings represent an indispensable paradigm for extreme concentration and amplification of propagating waves in space-time dimensions.
format Preprint
id arxiv_https___arxiv_org_abs_2411_08157
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Spatiotemporal Superfocusing
Yang, Qianru
Wu, Haotian
Hu, Hao
García-Vidal, F. J.
Hu, Guangwei
Luo, Yu
Optics
Superfocusing confines light within subwavelength structures, breaking the diffraction limit. Structures with spatial singularities, such as metallic cones, are crucial to enable nanoscale focusing, leading to significant advancements in nanophotonics, sensing, and imaging. Here, we exploit the spatiotemporal analogue of the wedge structure, i.e. a dielectric medium sandwiched between two subluminal interfaces with distinct velocities, to focus propagating waves beyond the diffraction limit, achieving spatiotemporal superfocusing. Within this structure, an incident pulse undergoes continuous spatial and temporal compression due to Doppler effects, which accumulates and results in an extreme focusing as it approaches the spatiotemporal vertex. Remarkably, unlike the field localization in conventional superfocusing, the compressed light in spatiotemporal wedges experiences significant amplification and then couple to the far field in free space. Our findings represent an indispensable paradigm for extreme concentration and amplification of propagating waves in space-time dimensions.
title Spatiotemporal Superfocusing
topic Optics
url https://arxiv.org/abs/2411.08157