Frequency-Self-Adaptive Radio Frequency Power Harvester Enabled by Shape-Reconfigurable Liquid Metal

Electromagnetic Science Pub Date : 2024-06-01 DOI:10.23919/emsci.2024.0008

Cheng Zhang;Yuchao Wang;Zebin Zhu;Hai Lin;Kun Wang;Xintong Shi;Yi Du;Chaoyun Song;Long Ren;Qiang Cheng

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Abstract

Radio frequency (RF) energy harvester as an efficient tool for capturing and converting the flourishing ambient RF energy provides a promising solution for long-term powering the wireless sensor networks and the Internet of things (IoTs). However, the actual distribution of the environmental RF signals is dynamically frequency-dependent due to the diverse wireless terminals only interacting with specified frequencies. To take full advantage of the RF energy carrying this characteristic, an intelligent RF energy harvester is in demand to automatically sense the frequency information of an incident signal and conduct the corresponding RF-to-direct current transformation process. Here, to the best of my knowledge, a frequency-self-adaptive RF harvester is first presented with the help of the shape-reconfigurable liquid metal, which can precisely identify and efficiently convert an arbitrary signal from the frequency span of 1.8 to 2.6 GHz. Companied with a microcontroller unit and a tensile system, the dynamic functionality of the entire system is comprehensively demonstrated, showing promising potential to significantly advance various fields, including sustainable IoT applications, green wearable technologies, and self-powered devices.

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利用形状可重构液态金属实现频率自适应射频功率收集器

射频（RF）能量收集器作为一种捕捉和转换蓬勃发展的环境射频能量的高效工具，为无线传感器网络和物联网（IoTs）的长期供电提供了一种前景广阔的解决方案。然而，由于各种无线终端只与特定频率互动，环境射频信号的实际分布与频率动态相关。为了充分利用携带这一特性的射频能量，需要一种智能射频能量收集器来自动感知入射信号的频率信息，并进行相应的射频-直流转换过程。据我所知，这里首次提出了一种频率自适应射频能量收集器，它借助可重新配置形状的液态金属，能够精确识别并有效转换频率跨度为 1.8 至 2.6 GHz 的任意信号。配合微控制器单元和拉伸系统，整个系统的动态功能得到了全面展示，在可持续物联网应用、绿色可穿戴技术和自供电设备等多个领域都显示出巨大的发展潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Electromagnetic Science

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