A natural-light-enabled self-powered system simultaneously monitoring wind speed, humidity, and irradiance in multiple channels

A natural-light-enabled self-powered system simultaneously monitoring wind speed, humidity, and irradiance in multiple channels

The self-powered internet of things (IoTs) is in high demand which eliminates batteries with limited lifetime and after-use environmental contaminations. Triboelectric nanogenerators can reveal environmental information through their charge transfer behavior, however, the signal pre-amplification is...

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Bibliographic Details
Published in:Nano energy Vol. 123; p. 109364
Main Authors: Wang, Jiaqi, Chen, Xingwen, Sun, Yifan, Qin, Xinghui
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-05-2024
Subjects:
Energy harvesting
Environmental monitoring
Liquid crystals
Ocean observation systems
Self-powered sensing
Triboelectric Nanogenerators
Triboelectric Nanogenerators
Energy harvesting
Self-powered sensing
Environmental monitoring
Liquid crystals
Ocean observation systems
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Summary:The self-powered internet of things (IoTs) is in high demand which eliminates batteries with limited lifetime and after-use environmental contaminations. Triboelectric nanogenerators can reveal environmental information through their charge transfer behavior, however, the signal pre-amplification is necessary consuming relatively high external energies and the sensing channels are greatly restricted by the limited information dimensions of the electrical outputs. Herein, we developed a fully-self-powered, natural-light-enabled sensing paradigm by integrating polymer network liquid crystals (PNLCs) triggered by rotary freestanding sliding TENGs (RFS-TENGs), color filters and optical fibers, where the friction-modulated natural light instead of the tribo-charge serves as the information carrier without the necessity of pre-amplification of the tribo-charge signal. Compared with previous TENG enabled self-powered sensors, the developed paradigm significantly expands the dimensions of sensed information, enabling simultaneous monitoring of multiple environmental factors including irradiance, wind speed, and humidity. Through the wavelength divisions of the sunlight via color filters, the self-powered sensing can be performed in multiple channels. Experimental validation in an indoor-simulated oceanic atmospheric boundary layer demonstrates the independence of the sensing under different channels, and ultrahigh sensing accuracies of 98.3%, 97.3%, and 96.7% for irradiance, wind speed, and humidity monitoring, respectively. [Display omitted] •A self-powered sensing system enabled by natural light modulated by environmental friction was developed.•Friction-modulated natural light rather than tribo-charge serves as the information carrier.•The natural light passing through the PNLC can be modulated by irradiance, humidity, and wind speed in the meanwhile.•Attributed to the sunlight wavelength division, the self-powered sensing in multiple channels is allowed.•The irradiance, wind speed, and humidity were profiled with the accuracies of 98.3%, 97.3%, and 96.7%.
ISSN:2211-2855
DOI:10.1016/j.nanoen.2024.109364