Synergy of light and acid-base reaction in energy conversion based on cellulose nanofiber intercalated titanium carbide composite nanofluidics

Employing chemical-potential with reverse electrodialysis is a sustainable way to generate electricity. Based on this observation, efforts have been made to utilize this energy, such as the development of nanomaterials and the introduction of external fields. However, the reported systems mainly foc...

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Bibliographic Details
Published inEnergy & environmental science Vol. 14; no. 8; pp. 44 - 449
Main Authors Liu, Pei, Zhou, Teng, Yang, Linsen, Zhu, Congcong, Teng, Yunfei, Kong, Xiang-Yu, Wen, Liping
Format Journal Article
LanguageEnglish
Published Cambridge Royal Society of Chemistry 11.08.2021
Subjects
Cellulose
Cellulose fibers
Electrodialysis
Energy
Energy conversion
Fluidics
Ion migration
Nanofibers
Nanofluids
Nanomaterials
Nanotechnology
Synergistic effect
Titanium
Titanium carbide
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Summary:Employing chemical-potential with reverse electrodialysis is a sustainable way to generate electricity. Based on this observation, efforts have been made to utilize this energy, such as the development of nanomaterials and the introduction of external fields. However, the reported systems mainly focus on a single type of physical field on the enhancement of energy conversion but ignore the synergy between cross-factor types. Here, we report a light and acid-base reaction enhanced energy conversion system based on 1D/2D composite nanofluidics. The contributions of light (physical) and acid-base reaction (chemical) in a chemical-potential-driven ionic generation system are studied separately and jointly. With the synergistic effect of the joint system, the output power density increases to 87.23 W m −2 , exceeding the output power density of the state-of-the-art membrane-based systems. Both experimental and theoretical results indicate that the physical-chemical synergistic effect can significantly improve the magnitude of ionic migration. Hence, our work demonstrates the vast potential of a physical-chemical synergistic assistant factor in the enhancement of chemical-potential-driven energy conversion. A light and acid-base reaction hybrid external factor-assisted energy conversion system is demonstrated based on MXene/CNF composite membranes, showing the great potential of physical-chemical hybrid assistant factors in enhancing energy conversion.
Bibliography:10.1039/d1ee00908g
Electronic supplementary information (ESI) available. See DOI
ISSN:1754-5692
1754-5706
DOI:10.1039/d1ee00908g