Integration of photothermal water evaporation with photocatalytic microplastics upcycling via nanofluidic thermal management

Photothermal heating and photocatalytic treatment are two solar-driven water processing approaches by harnessing NIR and UV-vis light, respectively, which can fully utilize solar energy if integrated. However, it remains a challenge to achieve high performance in both approaches when integrated in a...

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Published in:Proceedings of the National Academy of Sciences - PNAS 2024-03, Vol.121 (13), p.e2317192121-e2317192121
Main Authors: Meng, Xiangyu, Wang, Xin, Yin, Kuibo, Jing, Yao, Gu, Liuning, Tao, Zequan, Ren, Xinchuan, Tang, Mingyu, Shao, Xinxing, Sun, Litao, Sun, Yueming, Dai, Yunqian, Xiong, Yujie
Format: Article
Language:English
Subjects:
Acetic acid
Confinement
Evaporation
Evaporation rate
Fluidics
Heating
Mass transfer
Methyl acetate
Microplastics
Nanofibers
Nanofluids
Photocatalysis
Physical Sciences
Plastic pollution
Solar energy
Thermal management
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Summary:Photothermal heating and photocatalytic treatment are two solar-driven water processing approaches by harnessing NIR and UV-vis light, respectively, which can fully utilize solar energy if integrated. However, it remains a challenge to achieve high performance in both approaches when integrated in a material due to uncontrollable heat diffusion. Here, we report a demonstration of heat confinement on photothermal sites and fluid cooling on photocatalysis sites at the nanoscale, within a well-designed heat and fluid confinement nanofiber reactor. Photothermal and photocatalytic nanostructures were alternatively aligned in electrospun nanofibers for on-demand nanofluidic thermal management as well as easy folding into 3D structures with enhanced light utilization and mass transfer. Such a design showed simultaneously high photothermal evaporation rate (2.59 kg m h , exceeding the limit rate) and efficient photocatalytic upcycling of microplastics pollutant into valued products. Enabled by controlled photothermal heating, the valued main product (i.e., methyl acetate) can be evaporated out with 100% selectivity by in situ separation.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.2317192121