Patterned Surfaces for Solar-Driven Interfacial Evaporation

Luo, Yini; Fu, Benwei; Shen, Qingchen; Hao, Wei; Xu, Jiale; Min, Mengdie; Liu, Yanming; An, Shun; Song, Chengyi; Tao, Peng; Wu, Jianbo; Shang, Wen; Deng, Tao

doi:10.1021/acsami.8b20653

Cited by 56 publications

(31 citation statements)

References 30 publications

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“…The W‐doped VO 2 NPs were spray‐coated onto the PVDF thin film, which was polarized and covered by a thin layer of silver as the electrode (Experimental Section). The edge of the interfacial composite film was covered with an air‐laid paper with demonstrated wicking capability to ensure continuous supply of water to the VO 2 layer,34,35 which could quickly spread the water on the surface for evaporation due to its good wicking capability. A T‐type thermocouple was attached at the center of the bottom surface of PVDF layer to test the temperature of the film.…”

Section: Resultsmentioning

confidence: 99%

Bioinspired Temperature Regulation in Interfacial Evaporation

Jiang

Shen

Zhang

et al. 2020

Adv Funct Materials

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Human skin shows self‐adaptive temperature regulation through both enhanced heat dissipation in high temperature environments and depressed heat dissipation in cold environments. Inspired by such thermal regulation processes, an interfacial material system with self‐adaptive temperature regulation in the solar‐driven interfacial evaporation system, which can exhibit automatic temperature oscillation to enable pyroelectricity generation while producing water vapor, is reported. The bioinspired interface system is designed with the combination of a thermochromism‐based temperature regulator consisting of tungsten‐doped vanadium dioxide nanoparticles and a polymeric pyroelectric thin film of polyvinylidene fluoride. Under the simulated solar illumination with power density of 1.1 kW m−2, the bioinspired interfacial evaporation system achieves a self‐adaptive temperature oscillation with the maximum temperature difference of ≈7 °C and this system can simultaneously generate water vapor as well as electricity with an evaporation efficiency of 71.43% and a maximum output electrical power density of 104 µW m−2, respectively. The study demonstrates a design of thermal management at the interface of solar‐driven evaporation system to exhibit a self‐adaptive temperature oscillation and offers an alternative approach for the multifunctional harvesting of solar energy.

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Section: Resultsmentioning

confidence: 99%

Bioinspired Temperature Regulation in Interfacial Evaporation

Jiang

Shen

Zhang

et al. 2020

Adv Funct Materials

Self Cite

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“…The higher efficiency of PGF under solar illumination was attributed to three unique features of airlaid paper: i) enhanced light absorption owing to the structure-induced multi-scattering on the surface of the air-laid paper; ii) increased evaporative surface area because of the large surface roughness of the air-laid paper; and iii) restricted thermal diffusion due to low thermal conductivity of the paper substrate. [5] Air-laid paper has also been used to support photothermal materials, including RGO, [93e] carbon black, [98] carbon particle, [94] and polypyrrole (PPy). [93a] Besides being used as a supporting layer, air-laid paper has also been used as a hydrophilic wick to efficiently transport water for steam evaporation.…”

Section: Air-laid Papermentioning

confidence: 99%

Cellulose Nanomaterials in Interfacial Evaporators for Desalination: A “Natural” Choice

et al. 2020

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Herein, the recent advances in realizing highly efficient cellulose-based solar evaporators for alleviating the global water crisis are summarized. Fresh water scarcity is one of most threatening issues for sustainable development. Solar steam generation, which harnesses the abundant sunlight, has been recognized as a sustainable approach to harvest fresh water. In contrast to synthetic polymeric materials that can pose serious negative environmental impacts, cellulose-based materials, owing to their biocompatibility, renewability, and sustainability, are highly attractive for realizing solar steam generators. The molecular and macromolecular features of cellulose and the physicochemical properties of extracted cellulose nanoparticles (cellulose nanocrystals and cellulose nanofibrils) and natural cellulose materials (wood and bacterial nanocellulose) that make them attractive as supporting substrate materials in solar steam generators are briefly discussed. Recent progress in designing highly efficient cellulose-based solar evaporators, including utilizing the extracted cellulose nanoparticles via bottom-up assembly (cellulose nanofibrils), natural cellulose materials with intrinsic hierarchical structure (wood and bacterial nanocellulose), and commercial planar cellulose substrates (air-laid paper, cellulose paper and cotton fabric) is reviewed. The outstanding challenges that need to be addressed for these materials and devices to be utilized in the real-world and in overcoming global water crisis are also briefly highlighted.

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“…[3][4][5][6][7] In particular, solar-thermal processes are especially appealing to seawater desalination, space heating, construction, and solar-thermal storage systems. [8][9][10] However, solar radiation varies from time to time and place to place. In this respect, phase-changing materials (PCMs) with a large latent heat and heat storage density are considered efficient materials to resolve the time mismatch between the heat supply and actual consumption because PCMs can be exploited to store and release energy as a result of the phase change.…”

Section: Doi: 101002/advs202000602mentioning

confidence: 99%

Phase‐Changing Microcapsules Incorporated with Black Phosphorus for Efficient Solar Energy Storage

et al. 2020

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A new solar energy storage system is designed and synthesized based on phase-changing microcapsules incorporated with black phosphorus sheets (BPs). BPs are 2D materials with broad light absorption and high photothermal performance, which are synthesized and covalently modified with poly(methyl methacrylate) (PMMA) to produce the PMMA-modified BPs (mBPs). With the aid of PMMA, the mBPs and phase-changing materials (PCM, eicosane) are encapsulated together to form microcapsules. The microencapsulated eicosane and mBPs (mBPs-MPCM) composites exhibit a high latent heat of over 180 kJ kg −1 , good thermal reliability, as well as excellent photothermal characteristics inherited from BPs. Owing to the direct contact in the integrated mBPs-MPCM composites, the thermal energy generated by mBPs is transferred to eicosane immediately giving rise to three times higher efficiency in solar energy storage compared to microcapsules with mBPs on the surface. The mBPs-MPCM composites have great potential in solar energy storage applications and the concept of integrating photothermal materials and PCMs as the core provides insights into the design of high-efficiency solar energy storage materials. Solar energy is one of the most important renewable energy sources in the continuous efforts to meet the ever-increasing global energy demand [1,2] and techniques that capture solar

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Patterned Surfaces for Solar-Driven Interfacial Evaporation

Cited by 56 publications

References 30 publications

Bioinspired Temperature Regulation in Interfacial Evaporation

Bioinspired Temperature Regulation in Interfacial Evaporation

Cellulose Nanomaterials in Interfacial Evaporators for Desalination: A “Natural” Choice

Phase‐Changing Microcapsules Incorporated with Black Phosphorus for Efficient Solar Energy Storage

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