High Efficiency Solar Membranes Structurally Designed with 3D Core–2D Shell SiO<sub>2</sub>@Amino-Carbon Hybrid Advanced Composite for Facile Steam Generation

Li, Xibiao; Guan, Changlong; Gao, Xiaodong; Zuo, Xiahua; Yang, Weimin; Yan, Hua; Shi, Meinong; Li, Haoyi; Sain, Mohini

doi:10.1021/acsami.0c10461

Cited by 41 publications

(16 citation statements)

References 69 publications

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“…In addition, wetted surfaces can effectively reduce the surface scattering. [50,51] After wetting, the color of 80FLPD6-MCEP becomes darker and the absorbance is slightly enhanced. Therefore, the water evaporation rate over 80FLPD6-MCEP is better than that of 80FLPD6-MCE due to its higher hydrophilicity and stronger light absorption.…”

Section: Resultsmentioning

confidence: 99%

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

Shan

Xiong

Sheng

et al. 2020

Adv Energy and Sustain Res

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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.

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Section: Resultsmentioning

confidence: 99%

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

Shan

Xiong

Sheng

et al. 2020

Adv Energy and Sustain Res

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“…However, the intrinsic solar absorption of a material determines the upper limit of solar energy capture. Hence, in addition to the material itself, designing a light-trapping surface structure with open pores and channels would break this limit and further improve the solar absorption for better SVG performance by locking the solar irradiation into the surface. , The most common method for creating pores and channels in the evaporation layer is based on using prepared porous or fibrous templates as the substrate and then coating a solar absorbing layer on this substrate to obtain a light-trapping structure, which would complicate the fabrication process. , …”

Section: Introductionmentioning

confidence: 99%

Polypyrrole–Dopamine Nanofiber Light-Trapping Coating for Efficient Solar Vapor Generation

Jia

Gao

et al. 2021

ACS Appl. Mater. Interfaces

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Solar vapor generation (SVG) typically uses a solar absorbing material at the water–air interface to convert solar energy into heat for evaporation. However, the intrinsic solar absorption of the material determines the upper limit of the solar energy capture. By designing a light-trapping surface structure with open pores and channels, we can break this limit and further improve the absorption by enabling multiple reflections within the surface. Polypyrrole (PPy) is emerging as a promising solar thermal material. In this work, we propose an ultrasonic spray coating method to obtain a nanofiber light-trapping coating by copolymerization with dopamine (DA), which can be directly synthesized at room temperature rapidly (30 min). Due to its excellent wettability, this coating can transport water and can be directly coated on the thermal insulating layer, not requiring an additional water transport layer. This nanoscale coating significantly improves solar absorption at different incident angles across the full solar spectrum, achieving the highest solar-to-thermal conversion efficiency of 95.8% at 1.385 kg·m–2·h–1 under 1 sun. When applied on salt water, this solar evaporator achieves self-cleaning in the absence of solar irradiation. Moreover, the surface structure can be further tuned into granular/plane–fibrous/plane–granular structures by using different oxidants or surfactants, and their formation mechanisms are also proposed. This PPy–DA nanofiber coating shows great potential for SVG and other applications based on a PPy material, especially for those requiring a certain surface morphology.

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“…Thus far, various functional carbon materials, such as, 2D graphene‐based materials, carbon spheres and porous carbon flakes (PCFs), have been successfully synthesized by using PE, PP, PS, and other plastic wastes as precursors. [ 179–183 ]…”

Section: Rational Recycling Protocols Of Plastic Wastes To Eliminate ...mentioning

confidence: 99%

“…Li et al synthesized 2D-thin carbon film coated SiO 2 -based glass fiber membrane by using linear PE as the carbon source. [182] The thin PE derived carbon film was successfully coated on GF membrane at 900 °C, where the PE and GF were put in two different silica boats side by side in a tube muffle furnace. The modified membrane with 2D-thin carbon film remarkably enhanced the optical absorption and solar thermal conversion capability comparing with the pure glass fiber membrane.…”

Section: Pyrolysis Of Plastic Wastes For Generating Functional Carbon...mentioning

confidence: 99%

“…Thus far, various functional carbon materials, such as, 2D graphene-based materials, carbon spheres and porous carbon flakes (PCFs), have been successfully synthesized by using PE, PP, PS, and other plastic wastes as precursors. [179][180][181][182][183] Typically, traditional pyrolysis for transforming plastic wastes into functional carbons is comprised of two stages. First, the plastic wastes are heated at a relative low temperature (400-600 °C) for primary pyrolysis to obtain the amorphous or partial graphitized carbons, which is the so-called pre-carbonization.…”

Section: Pyrolysis Of Plastic Wastes For Generating Functional Carbon...mentioning

confidence: 99%

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How to Build a Microplastics‐Free Environment: Strategies for Microplastics Degradation and Plastics Recycling

et al. 2022

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Microplastics are an emergent yet critical issue for the environment because of high degradation resistance and bioaccumulation. Unfortunately, the current technologies to remove, recycle, or degrade microplastics are insufficient for complete elimination. In addition, the fragmentation and degradation of mismanaged plastic wastes in environment have recently been identified as a significant source of microplastics. Thus, the developments of effective microplastics removal methods, as well as, plastics recycling strategies are crucial to build a microplastics‐free environment. Herein, this review comprehensively summarizes the current technologies for eliminating microplastics from the environment and highlights two key aspects to achieve this goal: 1) Catalytic degradation of microplastics into environmentally friendly organics (carbon dioxide and water); 2) catalytic recycling and upcycling plastic wastes into monomers, fuels, and valorized chemicals. The mechanisms, catalysts, feasibility, and challenges of these methods are also discussed. Novel catalytic methods such as, photocatalysis, advanced oxidation process, and biotechnology are promising and eco‐friendly candidates to transform microplastics and plastic wastes into environmentally benign and valuable products. In the future, more effort is encouraged to develop eco‐friendly methods for the catalytic conversion of plastics into valuable products with high efficiency, high product selectivity, and low cost under mild conditions.

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High Efficiency Solar Membranes Structurally Designed with 3D Core–2D Shell SiO₂@Amino-Carbon Hybrid Advanced Composite for Facile Steam Generation

Cited by 41 publications

References 69 publications

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

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

Polypyrrole–Dopamine Nanofiber Light-Trapping Coating for Efficient Solar Vapor Generation

How to Build a Microplastics‐Free Environment: Strategies for Microplastics Degradation and Plastics Recycling

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High Efficiency Solar Membranes Structurally Designed with 3D Core–2D Shell SiO2@Amino-Carbon Hybrid Advanced Composite for Facile Steam Generation

Cited by 41 publications

References 69 publications

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

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

Polypyrrole–Dopamine Nanofiber Light-Trapping Coating for Efficient Solar Vapor Generation

How to Build a Microplastics‐Free Environment: Strategies for Microplastics Degradation and Plastics Recycling

Contact Info

Product

Resources

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High Efficiency Solar Membranes Structurally Designed with 3D Core–2D Shell SiO₂@Amino-Carbon Hybrid Advanced Composite for Facile Steam Generation