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Main Authors: Wan, Luyao, Zhang, Han, Li, Yunhui, Yang, Yaping, Chen, Hong, Guo, Zhiwei
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.07462
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author Wan, Luyao
Zhang, Han
Li, Yunhui
Yang, Yaping
Chen, Hong
Guo, Zhiwei
author_facet Wan, Luyao
Zhang, Han
Li, Yunhui
Yang, Yaping
Chen, Hong
Guo, Zhiwei
contents Topological wireless power transfer (WPT) technologies have attracted considerable interest due to their high transmission efficiency and robustness in coupled array configurations. However, conventional periodic and quasi-periodic topological chains exhibit limited adaptability in complex application scenarios, such as large-area simultaneous multi-load charging. In this work, we experimentally demonstrate a large-area topological defect state by constructing a gapless chain of uniformly coupled resonators at the interface of two topologically distinct Su-Schrieffer-Heeger (SSH) configurations. This topological defect state exhibits strong localization at multiple target sites, enabling efficient and concurrent wireless power delivery to spatially distributed loads. Furthermore, the unique wavefunction distribution enhances robustness against positional variations, ensuring stable energy transfer despite fluctuations in device placement. The proposed large-area topological framework offers fundamental insights into harnessing diverse topological states for advanced WPT applications, particularly in scenarios demanding spatial flexibility and multi-target energy delivery.
format Preprint
id arxiv_https___arxiv_org_abs_2505_07462
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Large-area topological wireless power transfer
Wan, Luyao
Zhang, Han
Li, Yunhui
Yang, Yaping
Chen, Hong
Guo, Zhiwei
Applied Physics
Topological wireless power transfer (WPT) technologies have attracted considerable interest due to their high transmission efficiency and robustness in coupled array configurations. However, conventional periodic and quasi-periodic topological chains exhibit limited adaptability in complex application scenarios, such as large-area simultaneous multi-load charging. In this work, we experimentally demonstrate a large-area topological defect state by constructing a gapless chain of uniformly coupled resonators at the interface of two topologically distinct Su-Schrieffer-Heeger (SSH) configurations. This topological defect state exhibits strong localization at multiple target sites, enabling efficient and concurrent wireless power delivery to spatially distributed loads. Furthermore, the unique wavefunction distribution enhances robustness against positional variations, ensuring stable energy transfer despite fluctuations in device placement. The proposed large-area topological framework offers fundamental insights into harnessing diverse topological states for advanced WPT applications, particularly in scenarios demanding spatial flexibility and multi-target energy delivery.
title Large-area topological wireless power transfer
topic Applied Physics
url https://arxiv.org/abs/2505.07462