Concentrated Acid‐Induced Dehydration of Fallen Leaves for Efficient, Sustainable, and Self‐Cleaning Solar Steam Generation

To develop solar steam generation (SGG) for water treatment, light absorbers have been widely synthesized by carbonization of plants at high temperature. However, the thermal treatment has high energy‐consumption and is environmentally unfriendly. Thus, it is urgent to explore new green approaches t...

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Bibliographic Details
Published in:Advanced energy and sustainability research 2020-12, Vol.1 (2), p.n/a
Main Authors: Shan, Xiaoli, Xiong, Meiyu, Sheng, Yuhang, Zhao, Aiqing, Di, Yunsong, Liu, Cihui, Gan, Zhixing
Format: Article
Language:English
Subjects:
Biomass
Carbon
carbonization
Cellulose
Clean energy
Cleaning
Dehydration
Enthalpy
Evaporation
Evaporation rate
Fourier transforms
Heat conductivity
Heat treatment
High temperature
hydrophilicity
Irradiation
Leaves
Membranes
Nitrogen
Oxygen plasma
photothermal effects
Polyvinyl alcohol
Seawater
solar steam generation
Spectrum analysis
Steam generation
Sulfuric acid
Sun
Water
Water shortages
Water treatment
Wettability
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Summary:To develop solar steam generation (SGG) for water treatment, light absorbers have been widely synthesized by carbonization of plants at high temperature. However, the thermal treatment has high energy‐consumption and is environmentally unfriendly. Thus, it is urgent to explore new green approaches to convert biomasses to carbon materials for SSG. Herein, a concentrated acid‐induced dehydration method is developed to convert fallen leaves to carbon powders, fallen‐leaf photothermal film prepared by dehydration (FLPD). The resultant FLPD exhibits a strong absorption covering a wide spectrum. It also contains sufficient oxygen‐containing groups on the surface, leading to low water evaporation enthalpy. To meet the demands of practical applications, the FLPD membrane is modified with polyvinyl alcohol (PVA) to improve the mechanical stabilities and the surface wettability is further enhanced by an oxygen plasma treatment. An SSG device based on the modified membrane attains a competitive evaporation rate of 1.355 kg m−2 h−1 under 1 sun irradiation. The evaporation rate remains approximately constant when evaporating the seawater. Moreover, the salt deposited on the surface could be self‐cleaned due to the high wettability. Therefore, herein, it is demonstrated that concentrated acid‐induced dehydration is an effective and green approach to convert cheap biomasses to carbon materials for SSG applications. Concentrated acid‐induced dehydration (CAID) is a green way to synthesize carbon materials from biomasses, which is developed for efficient solar steam generation (SGG) applications. The SGG based on carbonized leaves synthesized by CAID exhibits a high performance due to the good hydrophilicity and low water evaporation enthalpy.
ISSN:2699-9412
2699-9412
DOI:10.1002/aesr.202000034