Scalable Production of Integrated Graphene Nanoarchitectures for Ultrafast Solar-Thermal Conversion and Vapor Generation

Wu, Shenghao; Xiong, Guoping; Yang, Huachao; Tian, Yikuan; Gong, Biyao; Wan, Huiwen; Wang, Yan; Fisher, Timothy S.; Yan, Jun; Cen, Kefa; Bo, Zheng; Ostrikov, Kostya

doi:10.1016/j.matt.2019.06.010

Cited by 64 publications

(50 citation statements)

References 59 publications

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“…The excellent light-harvesting ability can be attributed to the unique morphology of N-fGNs, including the vertical orientation which is nearly parallel to the direction of incident light as well as the wall-like structures, open channels, and exposed edges. [39] When incident light reaches the graphene nanoarrays, it is trapped in the graphene nano-/microchannels and is then almost completely absorbed after multiple internal reflections. Importantly, the role of plasma in the synthesis can be summarized as follows: i) growing fGNs to obtain improved light absorption, ii) doping nitrogen species to achieve hydrophilic wettability, and iii) functionalizing the nanoarchitectures to obtain surface waterways (see more details in Section S6 in the Supporting Information).…”

Section: Characterization Of the N-fgn/sgf Nanoarchitecturesmentioning

confidence: 99%

Multifunctional Solar Waterways: Plasma‐Enabled Self‐Cleaning Nanoarchitectures for Energy‐Efficient Desalination

Xiong

Yang

et al. 2019

Advanced Energy Materials

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118

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Evaporating seawater and separating salt from water is one of the most promising solutions for global water scarcity. State‐of‐the‐art water desalination devices combining solar harvesting and heat localization for evaporation using nanomaterials still suffer from several issues in energy efficiency, long‐term performance, salt fouling, light blocking, and clean water collection in real‐world applications. To address these issues, this work devises plasma‐enabled multifunctional all‐carbon nanoarchitectures with on‐surface waterways formed by nitrogen‐doped hydrophilic graphene nanopetals (N‐fGPs) seamlessly integrated onto the external surface of hydrophobic self‐assembled graphene foam (sGF). The N‐fGPs simultaneously transport water and salt ions, absorb sunlight, serve as evaporation surfaces, then capture the salts, followed by self‐cleaning. The sGF ensures effective thermal insulation and enhanced heat localization, contributing to high solar‐vapor efficiency of 88.6 ± 2.1%. Seamless connection between N‐fGPs and sGF and self‐cleaning of N‐fGP structures by redissolution of the captured salts in the waterways lead to long‐term stability over 240 h of continuous operation in real seawater without performance degradation, and a high daily evaporation yield of 15.76 kg m−2. By eliminating sunlight blocking and guiding condensed vapor, a high clean water collection ratio of 83.5% is achieved. The multiple functionalities make the current nanoarchitectures promising as multipurpose advanced energy materials.

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Section: Characterization Of the N-fgn/sgf Nanoarchitecturesmentioning

confidence: 99%

Multifunctional Solar Waterways: Plasma‐Enabled Self‐Cleaning Nanoarchitectures for Energy‐Efficient Desalination

Xiong

Yang

et al. 2019

Advanced Energy Materials

Self Cite

118

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“…Instead, the results would be more reasonable and consistent with experimental observations if the temperature of the hot water vapor zone that exists closely to the evaporation surface is considered. [ 25,80–82 ] However, the measurement strategies and the precise boundary condition for this is not yet settled.…”

Section: Design Principles To Approach 100% Efficiencymentioning

confidence: 99%

“…More confined water pathways were proposed to minimize the contact with water, thus saving the heat from conduction loss. 2D water supply employs hydrophilic intermediary materials such as cellulose, [ 91 ] cotton and silk fabrics, [ 47,92–94 ] vertically oriented graphene structures, [ 81 ] air‐laid paper, [ 95 ] etc., for water delivery. In this way only a thin confined water layer is in contact with solar absorbers to supply water for evaporation (Figure 4b).…”

Section: Design Principles To Approach 100% Efficiencymentioning

confidence: 99%

“…It was also found that the absorption reached to its maximum (≈99%) with 10 layers of PPy nanosheets, implying that this effect is deliberately tunable. Photothermal structures with orderly and randomly aligned structures, [ 56,58,90,106 ] especially those vertically oriented nanostructures such as the graphene nanosheets highlighted in Figure 5c, [ 81 ] have also been considered as an important group of materials with superior properties for solar thermal conversion. These oriented structures not only enable broadband light absorption, but also, they are further capable of ultrafast solar thermal response.…”

Section: Design Principles To Approach 100% Efficiencymentioning

confidence: 99%

“…Reproduced with permission. [ 81 ] Copyright 2019, Elsevier. d): 1) Fabrication process, 2) Optical photographs and corresponding SEM images of low‐cost hierarchical aluminum‐based solar absorber with plasmonic Al nanoparticles.…”

Section: Design Principles To Approach 100% Efficiencymentioning

confidence: 99%

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Structure Architecting for Salt‐Rejecting Solar Interfacial Desalination to Achieve High‐Performance Evaporation With In Situ Energy Generation

et al. 2020

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requirement has given rise to research thrusts being focused on the development of solar-driven evaporation based desalination technologies. [4][5][6][7] The research on using solar energy in the desalination process has a long history. [3,8,9] In a traditional singleslope basin-like solar still (Figure 1a), saline water is heated and subsequently evaporated by directly exposing to solar radiation. Solar energy is absorbed and converted into thermal energy by a black light-absorbing liner that is situated at the bottom of the solar basin. [10] Due to this design, the solar absorber is immersed in bulk seawater and it hardly receives a fraction of the incoming solar radiation owing to poor light penetration through the thick water layer. Furthermore, the produced heat is easily dissipated into the bulk water, and further lost to the surroundings through water surface radiation, convection and conduction. Due to the above reasons, the resulting solar-tosteam conversion efficiency is inevitably low. Nanoparticle dispersed fluid was then demonstrated to harness solar energy and found to be a great boon to direct water vapor generation. [11,12] A solar conversion efficiency of up to ≈70% can be possibly achieved because heat loss to bulk water is mitigated ( Figure 1b). [13,14] However, research on this advancement didn't last because of the development of solar interfacial heating strategy, which is shown in Figure 1c. The concept of interfacial evaporation was first put forth in 2014 by two reports simultaneously, [15,16] and received a surge of attention and interest immediately in the following years. The most prominent feature of solar interfacial evaporation lies in the position of the solar absorber, which is at the interface between saline liquid and the above air. This special configuration not only minimizes heat loss from the solar absorber to bulk water, but also provides significantly more surface area for prompt vapor release. Also, solar radiation is photothermally localized at the surface of solar absorber, giving rise to high surface temperature, which enables fast heat transfer to water. With it, water transported from reservoir can be heated and evaporated immediately to achieve a higher rate of steam generation. In addition to the differences in heating strategies, it should be noted that all the solar stills follow the same evaporation-condensation route for desalination and clean water collection, and to this end, a similar device structure (e.g., solar still with sloping cover) is usually employed.The past few years have witnessed a rapid development of solar-driven interfacial evaporation, a promising technology for low-cost water desalination. As of today, solar-to-steam conversion efficiencies close to 100% or even beyond the limit are becoming increasingly achievable in virtue of unique photothermal materials and structures. Herein, the cutting-edge approaches are summarized, and their mechanisms for photothermal structure architecting are uncovered in order to achieve ultrahigh conversion e...

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Intensifying Heat Using MOF‐Isolated Graphene for Solar‐Driven Seawater Desalination at 98% Solar‐to‐Thermal Efficiency

Han

Besteiro

Koh

et al. 2021

Adv Funct Materials

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Photothermal materials are crucial for diverse heating applications, but it remains challenging to achieve high energy conversion efficiency due to the difficulty to concurrently improve light absorbance and suppress heat loss. Herein, a zeolitic imidazolate framework‐isolated graphene (G@ZIF) nanohybrid is demonstrated that utilizes ultrathin, heat‐insulating ZIF layers, and G@ZIF interfacial nanocavity to synergistically intensify light absorbance and heat localization. Under artificial sunlight illumination (≈1 kW m−2), the G@ZIF film attains a maximum temperature of 120 °C in an open environment with a 98% solar‐to‐thermal conversion efficiency. Importantly, the porous ZIF layer allows small molecules/media to enter and access the embedded hot graphene surface for targeted heat transfer in practical applications. As a proof‐of‐concept, the G@ZIF‐based steam generator realizes 96% energy conversion from light to vapor with near‐perfect desalination and water purification efficiencies (>99.9%). This design is generic and can be extended to other photothermal systems for advanced solar‐thermal applications, including catalysis, water treatments, sterilization, and mechanical actuation.

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Scalable Production of Integrated Graphene Nanoarchitectures for Ultrafast Solar-Thermal Conversion and Vapor Generation

Cited by 64 publications

References 59 publications

Multifunctional Solar Waterways: Plasma‐Enabled Self‐Cleaning Nanoarchitectures for Energy‐Efficient Desalination

Multifunctional Solar Waterways: Plasma‐Enabled Self‐Cleaning Nanoarchitectures for Energy‐Efficient Desalination

Structure Architecting for Salt‐Rejecting Solar Interfacial Desalination to Achieve High‐Performance Evaporation With In Situ Energy Generation

Intensifying Heat Using MOF‐Isolated Graphene for Solar‐Driven Seawater Desalination at 98% Solar‐to‐Thermal Efficiency

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