Durable, scalable and affordable iron (III) based coconut husk photothermal material for highly efficient solar steam generation

Pham, Thanh-Dong; Nguyen, Thanh Phuc; Nguyen, Thi An Hang; Pham, Dinh Dat; Nguyen, Duc Cuong; Bich, Danh; Nguyen, Hoai Viet; Ha, Minh Hiep; Nguyen, Zoom

doi:10.1016/j.desal.2021.115280

Cited by 54 publications

(27 citation statements)

References 36 publications

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“…11,12 Although extensive progress has been made using several device structures, the low evaporation rate (<2 kg m −2 h −1 ) and salt accumulation cause severe degradation of the evaporation rate, thus limiting the photothermal evaporator performance. 13,14…”

Section: Introductionmentioning

confidence: 99%

Extremely high-efficiency solar steam generation, robust and scalable photothermal evaporator based on ZIF-67@MXene/rGO decorated rock wool

et al. 2023

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Section: Introductionmentioning

confidence: 99%

Extremely high-efficiency solar steam generation, robust and scalable photothermal evaporator based on ZIF-67@MXene/rGO decorated rock wool

et al. 2023

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“…Natural biomass‐based absorbers, among many other solar absorber materials, have the advantages of increased porosity, biodegradability, low thermal conductivity, and cheaper cost, making them suitable for mass manufacturing. Recently, carbonized lotus leaf, [ 127 ] wood−graphene oxide composites, [ 62 ] carbonized daikon (CD), [ 110 ] mesostructured natural wood with a carbonized surface, [ 128 ] carbonized rose/straw/coffee powder, [ 127,129,130 ] sunflower heads after carbonization, [ 79 ] carbonized corncob (CC), [ 73 ] luffa sponge with candle soot coating, [ 49 ] carbonized bamboo, [ 47 ] fresh radish immersed into a dime‐thylformamidel‐based solution, [ 70 ] carbonized sawdust beds, [ 131 ] carbonized mushrooms, [ 60 ] halloyste nanotubes with wood fiber, [ 132 ] carbonized coconut husk (CCH), [ 83 ] carbonized tofu (CT), and [ 133 ] carbonized magnolia fruit (CMF) [ 134 ] are vastly used for interfacial vapor generation owing to their cost efficiency, low thermal conductivity, and environment‐friendly and scalable properties. Moreover, plasmonic materials‐coated natural biomass such as TiN NPs coated on carbonized wood, [ 135 ] Ag−polydopamine (PDA) NPs loaded on wooden flower, [ 56 ] and plasmonic Ag NPs coated on bamboo [ 136 ] have been demonstrated with higher optical absorption.…”

Section: Fundamental Mechanism Of Photothermal Conversionmentioning

confidence: 99%

“…[ 50–53 ] However, at the same time, the naturally found porous materials often provide relatively lower solar absorbance, which has been addressed by providing an extra layer of coating using nanomaterials [ 54–56 ] or chemical treatment [ 49,57,58 ] and carbonization of the materials. [ 36,55,59–61 ] Among many natural porous materials, wood, [ 62–68 ] mushroom, [ 60,69 ] straw, [ 55 ] radish, [ 70,71 ] corncob, [ 72,73 ] bamboo, [ 47,51,74,75 ] lotus seedpods and leaf, [ 59,76 ] carrot, [ 77,78 ] sunflower head, [ 79,80 ] luffa sponge, [ 49,81,82 ] coconut husk, [ 83 ] rice husk, [ 84,85 ] etc. are the most commonly investigated natural porous materials for the ISSG‐based system.…”

Section: Introductionmentioning

confidence: 99%

Natural Porous Materials for Interfacial Solar Steam Generation toward Clean Water Production

et al. 2022

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Food along with water, clothes, and shelter has long been considered as basic necessities for human life. [1] However, the reality is that people all around the globe continue to have difficulties in fulfilling their fundamental survival requirements. Rising population, unplanned urbanization, climate change, global energy, and natural resource crises are exacerbating these issues. Despite the fact that water covers more than three-quarters of the Earth's surface, providing fresh water as a fundamental requirement in certain drought-prone areas remains a problem. [2,3] Reducing the conflict between demand and availability for fresh water has become a significant problem in recent decades. According to World Health Organization (WHO), a shortage of freshwater resources may impact half of the world's population in the near future. [4,5] As a result, reliance on nontraditional sources, that is, purification of saltwater, sewage, and industrial effluents, must be increased to ease pressure on conventional water sources. [6][7][8] However, excessive levels of germs and hard particles in water from nontraditional sources may induce illnesses such as typhoid, jaundice, cholera, dysentery, and others. [9] Nevertheless, identifying alternative freshwater sources and implementing sustainable techniques for reusing and recycling water from unconventional sources may be a viable way to address the worldwide problem of freshwater shortage.Recent research on the generation of freshwater has revealed that methods such as reverse osmosis, electrodialysis, thermal desalination, and multiple-effect distillation need a high consumption of fossil fuels, a substantial initial investment, and the emission of polluting gas. [10][11][12] Thus, an interfacial solar-driven steam generation (ISSG)-based system is always recommended as a good candidate for seawater desalination, sterilizing, and wastewater treatment owing to its sustainability, cost-effectiveness, environmental friendliness, as well as ease of operation. In contrast to the natural water evaporation system, the ISSG-based system uses the heat localization method to heat only the portion of water which is associated with the airÀwater interface rather than the bulk water, substantially increasing the water evaporation rate. This technique utilizes the radiant heat from the sun with the assistance of photothermal energy conversion material, making it a promising sustainable solution to the water crisis. Furthermore, with proper design, heat loss can be minimized, allowing this technique to generate enough steam for water desalination, purification, and many other applications. [13][14][15][16][17][18][19] The selection of photothermal energy conversion materials for the ISSG mainly depends on the material's optical absorption spectra, photothermal conversion efficiency, sustainability, and duration of transmitting water to the heating surface (Figure 1). Researchers have investigated many naturally processed materials and nanoparticles (NPs) to design an efficient

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“…SDIE has aroused great interest from researchers due to its advantages of green environmental protection, low cost and adjustable scale. 1–3 In recent years, increasing types of photothermal materials (PMs) have been designed based on interfacial evaporation, mainly including natural products, 4–10 polymers, 11–15 carbon materials, 16–21 and semiconductors. 22–27 Besides, the functions of the developed PMs are becoming increasingly comprehensive, mainly covering long-term salt resistance, 6,28–32 self-cleaning 33–37 and collaborative power generation.…”

Section: Introductionmentioning

confidence: 99%

Solar-driven interfacial evaporation for water treatment: advanced research progress and challenges

Jing

Xing

et al. 2022

J. Mater. Chem. A

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Durable, scalable and affordable iron (III) based coconut husk photothermal material for highly efficient solar steam generation

Cited by 54 publications

References 36 publications

Extremely high-efficiency solar steam generation, robust and scalable photothermal evaporator based on ZIF-67@MXene/rGO decorated rock wool

Extremely high-efficiency solar steam generation, robust and scalable photothermal evaporator based on ZIF-67@MXene/rGO decorated rock wool

Natural Porous Materials for Interfacial Solar Steam Generation toward Clean Water Production

Solar-driven interfacial evaporation for water treatment: advanced research progress and challenges

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