Sustainable power generation for at least one month from ambient humidity using unique nanofluidic diode

The continuous energy-harvesting in moisture environment is attractive for the development of clean energy source. Controlling the transport of ionized mobile charge in intelligent nanoporous membrane systems is a promising strategy to develop the moisture-enabled electric generator. However, existi...

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Bibliographic Details
Published in:Nature communications 2022-06, Vol.13 (1), p.3484-3484, Article 3484
Main Authors: Zhang, Yong, Yang, Tingting, Shang, Kedong, Guo, Fengmei, Shang, Yuanyuan, Chang, Shulong, Cui, Licong, Lu, Xulei, Jiang, Zhongbao, Zhou, Jian, Fu, Chunqiao, He, Qi-Chang
Format: Article
Language:English
Subjects:
639/4077/4072/4062
639/925/927/351
Charge transfer
Chemical reduction
Clean energy
Clean technology
Electric fields
Electric generators
Electric potential
Energy
Energy conversion
Energy conversion efficiency
Energy harvesting
Energy sources
Engineering Sciences
Fluidics
Humanities and Social Sciences
Humidity
Ion charge
Ion migration
Membranes
Moisture effects
multidisciplinary
Nanofluids
Oxidation
Oxidation-reduction potential
P-n junctions
Redox reactions
Science
Science (multidisciplinary)
Sustainable energy
Voltage
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Summary:The continuous energy-harvesting in moisture environment is attractive for the development of clean energy source. Controlling the transport of ionized mobile charge in intelligent nanoporous membrane systems is a promising strategy to develop the moisture-enabled electric generator. However, existing designs still suffer from low output power density. Moreover, these devices can only produce short-term (mostly a few seconds or a few hours, rarely for a few days) voltage and current output in the ambient environment. Here, we show an ionic diode–type hybrid membrane capable of continuously generating energy in the ambient environment. The built-in electric field of the nanofluidic diode-type PN junction helps the selective ions separation and the steady-state one-way ion charge transfer. This directional ion migration is further converted to electron transportation at the surface of electrodes via oxidation-reduction reaction and charge adsorption, thus resulting in a continuous voltage and current with high energy conversion efficiency. Energy harvesting of humidity present in air can be used for the development of clean energy sources and self-sustained systems. The authors propose a nanofluid energy conversion system with integrated ionic diode-type hybrid membrane for energy generation in environmental moisture.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-022-31067-z