Implementing Hybrid Energy Harvesting in 3D Spherical Evaporator for Solar Steam Generation and Synergic Water Purification

Lü, Yi; Fan, Deqi; Xu, Haolan; Min, Huihua; Lu, Chunhua; Lin, Zhien; Yang, Xiaofei

doi:10.1002/solr.202000232

Cited by 93 publications

(58 citation statements)

References 73 publications

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“…

{normalT}_{0}

represents the evaporation point temperature, and T w represents the seawater temperature at room temperature. [ 24 ] After calculation, the photothermal conversion efficiency under 1, 3, and 5 sun is 83.84%, 84.23%, and 84.02%, respectively. It proves that NiS 2 @Ti 3 C 2 has excellent light‐to‐heat conversion efficiency and is a promising material for light‐to‐heat evaporation of seawater.…”

Section: Resultsmentioning

confidence: 99%

NiS₂ Nanocubes Coated Ti₃C₂ Nanosheets with Enhanced Light‐to‐Heat Conversion for Fast and Efficient Solar Seawater Steam Generation

Wang

et al. 2021

Solar RRL

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Recently, 2D materials have emerged in the field of light‐to‐heat conversion. However, it is urgent to find a simple and effective method to reduce the light reflectivity of the 2D surface to improve the light‐to‐heat conversion efficiency. A 2D nano‐self‐assembly material coating (NiS2@Ti3C2) realized by a simple hydrothermal method, which enables unique‐sized nano‐NiS2 crystals and 2D Ti3C2–MXenes to self‐assemble on a 3D scale, is innovatively proposed. Such a preparation method can construct a unique multilayer structure for multistage diffuse reflection of incident light, so that the MXene nanomaterial can achieve a light absorption rate of >90% in a wide spectral range. The composite is theoretically verified through optical simulation and first principles, and a higher light‐to‐heat conversion performance is achieved experimentally (61.7 °C surface equilibrium temperature, 1 sun). Compared with other similar materials, the assembled MXene seawater steam generator achieves a higher steam generation rate (1.27 kg m−2 h−1) and light‐to‐heat conversion efficiency (83.84%) under 1 sun. This material structure can maximize MXene active materials’ utilization and provide ideas for modifying other 2D photothermal materials.

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“…

{normalT}_{0}

Section: Resultsmentioning

confidence: 99%

NiS₂ Nanocubes Coated Ti₃C₂ Nanosheets with Enhanced Light‐to‐Heat Conversion for Fast and Efficient Solar Seawater Steam Generation

Wang

et al. 2021

Solar RRL

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“…[ 27,41,52,68 ] More recently, novel 3D photothermal evaporators were developed which successfully boosted the evaporation rate and exceeded the theoretical limit of light‐to‐vapor energy conversion efficiency. [ 23–25,69–76 ] This was achieved by introducing additional cold evaporation surfaces with a lower surface temperature than the surrounding environment to harvest additional energy from the surrounding air to enhance water evaporation. [ 69,70,72–74,76 ] Such 3D evaporators have also shown the ability to take advantage of convective air flow, [ 23,26 ] recycle latent heat released from vapor condensation, [ 25,77 ] and extract energy from bulk water to enhance solar steam generation.…”

Section: Introductionmentioning

confidence: 99%

A Hollow and Compressible 3D Photothermal Evaporator for Highly Efficient Solar Steam Generation without Energy Loss

et al. 2021

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Solar steam generation offers a sustainable strategy to mitigate global clean water scarcity. To this end, 3D photothermal evaporators have attracted increasing research interest since they can significantly improve both evaporation rate and energy efficiency. However, compared to the 2D evaporators, the 3D ones consume more raw materials and occupy more storage space, which limits their applications for practical portable solar steam generation. To address this issue, a 3D hollow and compressible photothermal evaporator is designed and fabricated which can be compressed to less than one third of its original volume, thus enabling easier transport and storage. Moreover, under 1.0 sun illumination, all evaporation surfaces of this 3D evaporator are lower in temperatures than the surrounding environment, thus providing the unique advantage of zero energy loss to the environment during solar evaporation. Due to the all‐cold evaporation surfaces, during solar evaporation, the evaporator is able to harvest massive energy from both the surrounding air and bulk water, delivering an extremely high evaporation rate of up to 7.6 kg m−2 h−1 under 1.0 sun irradiation. Furthermore, seawater desalination tests demonstrate that the device has great potential for portable solar thermal desalination by delivering clean water with a salinity well below 50 ppb.

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“…With the ever-increasing demand of clean and renewable energy resources [1][2][3][4], considerable attention has been devoted to the development of novel materials toward efficient solar cells [5][6][7][8][9][10][11][12][13][14]. As a family of important two-dimensional materials, MXenes, layered carbides and nitrides of transition metals first reported by the Gogotsi group in 2011 [15], which have been extensively investigated in various fields including energy storage [16][17][18][19][20][21][22], biomedical fields [23][24][25], electromagnetic applications [26][27][28][29], sensors [30][31][32][33][34], light-emitting diodes [35][36][37], water purification [38][39][40][41][42][43] and catalysis [44][45][46]…”

Section: Introductionmentioning

confidence: 99%

MXenes for Solar Cells

et al. 2021

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Application of two-dimensional MXene materials in photovoltaics has attracted increasing attention since the first report in 2018 due to their metallic electrical conductivity, high carrier mobility, excellent transparency, tunable work function and superior mechanical property. In this review, all developments and applications of the Ti3C2Tx MXene (here, it is noteworthy that there are still no reports on other MXenes’ application in photovoltaics by far) as additive, electrode and hole/electron transport layer in solar cells are detailedly summarized, and meanwhile, the problems existing in the related studies are also discussed. In view of these problems, some suggestions are given for pushing exploration of the MXenes’ application in solar cells. It is believed that this review can provide a comprehensive and deep understanding into the research status and, moreover, helps widen a new situation for the study of MXenes in photovoltaics.

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Implementing Hybrid Energy Harvesting in 3D Spherical Evaporator for Solar Steam Generation and Synergic Water Purification

Cited by 93 publications

References 73 publications

NiS₂ Nanocubes Coated Ti₃C₂ Nanosheets with Enhanced Light‐to‐Heat Conversion for Fast and Efficient Solar Seawater Steam Generation

NiS₂ Nanocubes Coated Ti₃C₂ Nanosheets with Enhanced Light‐to‐Heat Conversion for Fast and Efficient Solar Seawater Steam Generation

A Hollow and Compressible 3D Photothermal Evaporator for Highly Efficient Solar Steam Generation without Energy Loss

MXenes for Solar Cells

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Implementing Hybrid Energy Harvesting in 3D Spherical Evaporator for Solar Steam Generation and Synergic Water Purification

Cited by 93 publications

References 73 publications

NiS2 Nanocubes Coated Ti3C2 Nanosheets with Enhanced Light‐to‐Heat Conversion for Fast and Efficient Solar Seawater Steam Generation

NiS2 Nanocubes Coated Ti3C2 Nanosheets with Enhanced Light‐to‐Heat Conversion for Fast and Efficient Solar Seawater Steam Generation

A Hollow and Compressible 3D Photothermal Evaporator for Highly Efficient Solar Steam Generation without Energy Loss

MXenes for Solar Cells

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Product

Resources

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NiS₂ Nanocubes Coated Ti₃C₂ Nanosheets with Enhanced Light‐to‐Heat Conversion for Fast and Efficient Solar Seawater Steam Generation

NiS₂ Nanocubes Coated Ti₃C₂ Nanosheets with Enhanced Light‐to‐Heat Conversion for Fast and Efficient Solar Seawater Steam Generation