Simultaneously achieving thermal insulation and rapid water transport in sugarcane stems for efficient solar steam generation

Solar steam generation has attracted increasing attention due to its applications in water purification ( e.g. , desalination and wastewater treatment). Many strategies have been developed for achieving efficient photothermal conversion materials based on abundant biomass. However, it is challenging...

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Published in:Journal of materials chemistry. A, Materials for energy and sustainability Materials for energy and sustainability, 2019, Vol.7 (15), p.9034-9039
Main Authors: Liu, Jie, Liu, Qinglei, Ma, Dongling, Yuan, Yang, Yao, Jiahao, Zhang, Wang, Su, Huilan, Su, Yishi, Gu, Jiajun, Zhang, Di
Format: Article
Language:English
Subjects:
Biomass
Boilers
Bundles
Desalination
Evaporation
Fabrication
Flow velocity
Heat conductivity
Heat transfer
Illumination
Insulators
Mass transport
Mathematical analysis
Nutrition
Parenchyma
Photothermal conversion
Pore size
Pore size distribution
Porosity
Purification
Size distribution
Steam generation
Stems
Sugarcane
Sun
Temperature distribution
Thermal conductivity
Thermal insulation
Wastewater treatment
Water flow
Water purification
Water transport
Water treatment
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Summary:Solar steam generation has attracted increasing attention due to its applications in water purification ( e.g. , desalination and wastewater treatment). Many strategies have been developed for achieving efficient photothermal conversion materials based on abundant biomass. However, it is challenging for most of these materials to simultaneously facilitate water transport and manage heat well, which results in unsatisfactory evaporation efficiencies under 1 sun illumination. Here, inspired by natural sugarcane stems' bi-functional structures—vascular bundles for mass transport and parenchyma cells for nutrition storage, we use surface-carbonized de-sugaring stems of sugarcane as efficient solar steam generators. The obtained materials have abundant “closed chambers” for thermal insulation ( ca. 0.08 W m −1 K −1 in thermal conductivity) and bundles of vertical channels for water transport. These materials achieve an evaporation conversion efficiency up to 87.4% under 1 sun illumination without the usage of additional thermal insulators. This value surpasses all other biomass-derived materials ever reported. Because such bi-functional structures also widely exist in the stems of other Poaceae plants that are renewable and abundant in nature, this strategy is expected to open a new avenue for the future design and fabrication of diverse, more efficient, and cost-effective photothermal-conversion devices.
ISSN:2050-7488
2050-7496
DOI:10.1039/C9TA00843H