Hierarchical Porous Carbonized Lotus Seedpods for Highly Efficient Solar Steam Generation

Fang, Jing; Liu, Jie; Gu, Jiajun; Liu, Qinglei; Zhang, Wang; Su, Huilan; Zhang, Di

doi:10.1021/acs.chemmater.8b01702

Cited by 211 publications

(151 citation statements)

References 41 publications

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“…Without the formation of plenty of other gases (CO 2 or H 2 ), the inner wall of the tunnel is kept thick (Figure c) . The C‐FFNC sample as an SISG sample can form localized evaporation (Figure f and inset picture), where simulated seawater can be transported naturally through its pores under the capillary force and the hydrophilic character of starch . As shown in Figure g, the IR image of the SISG device under 1 sun radiation in 1 min, the localized hot region can be obviously observed.…”

Section: Resultsmentioning

confidence: 95%

“…Recently, biomass materials with natural ubiquitous micro‐ and macrostructures, such as mushroom, lotus, cotton, wood, daikon, louts leaf, are developed as an efficient solar steam generation device by a series of simple processing, i.e., cutting, freeze drying, and high‐temperature carbonization (Figure S1, Supporting Information). Some simple treatments for biomass materials have produced unique advantages for synthetic materials (Table and Table S1, Supporting Information) .…”

Section: Introductionmentioning

confidence: 99%

“…Due to different natural mesoporous structures in natural wood, it is also used to investigate the effect of water transport and heat transfer on the evaporation efficiency. The carbonized lotus seedpods with a high evaporation efficiency (86.5% at 1 kW m −2 ) mainly relied on their unique macroscopic cone shape and hierarchical mesopores and macropore structures . Moldy bread, carbonized by a barbecue‐like method, achieves a 71.4% evaporation efficiency in a high humidity level (70%) .…”

Section: Introductionmentioning

confidence: 99%

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Efficient Interfacial Solar Steam Generator with Controlled Macromorphology Derived from Flour via “Dough Figurine” Technology

Wang

et al. 2019

Energy Tech

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A solar‐driven interface steam generator (SISG) has potential applications in saline water desalination and polluted water purification. A shape‐ and size‐controlled, low‐cost, eco‐friendly solar‐absorber material is urgently desired for practical applications of SISGs. Herein, a facile, sustainable, and scalable approach is proposed to produce tailored SISGs with controlled macromorphology derived from flour via “dough figurine” technology originating from the China Han Dynasty. Three kinds of self‐floated flour‐based absorbers, i.e., near‐cylindrical (integrated), near‐spherical (loose packing), and powdery (dense packing) absorber used as SISGs, are discussed. More importantly, it is found that the macromorphology significantly influences water transport and interfacial thermal management of SISGs; thus the integrated absorber has an obvious advantage over the other two absorbers, which possesses a high evaporation efficiency of 71.9% at normal solar illumination. The proposed “dough figurine” technology breaks the limitations of the inherent geometry of reported biomass‐based SISGs, which provides an important guidance for SISG use in remote and impoverished areas.

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Section: Resultsmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Efficient Interfacial Solar Steam Generator with Controlled Macromorphology Derived from Flour via “Dough Figurine” Technology

Wang

et al. 2019

Energy Tech

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“…[85] Inspired by this technology, many researchers used some common, abundant, and low-cost organic porous materials (e.g., foam, [67,[86][87][88] lotus seedpods, [89] wood, [64] bamboo, [90] and cotton [66] ) to readily fabricate different photothermal convertors. [85] Inspired by this technology, many researchers used some common, abundant, and low-cost organic porous materials (e.g., foam, [67,[86][87][88] lotus seedpods, [89] wood, [64] bamboo, [90] and cotton [66] ) to readily fabricate different photothermal convertors.…”

Section: Carbonized Materialsmentioning

confidence: 99%

“…[65] Similarly, a cotton rod was designed as the stem of umbrella-like solar evaporator to act as 1D water supply channel. Until now, numerous 3D porous materials have been applied to efficiently pump up water into solar absorber, including cellulose fabric, [3] lotus seedpods, [89] hydrophilic poly(tetra-fluoroethylene) (PTFE) membrane, [130] cotton, [66] aerogels, [131] sponge, [132] and hydrogel. Besides, a confined 2D water pathway was designed for water supplies of solar absorber (laminated GO film) through a thin cellulose layer wrapped over the surface of a thermal insulator in 2016.…”

Section: Strategies For Enhancing Water Evaporation Efficiencymentioning

confidence: 99%

Harnessing Solar‐Driven Photothermal Effect toward the Water–Energy Nexus

et al. 2019

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Producing affordable freshwater has been considered as a great societal challenge, and most conventional desalination technologies are usually accompanied with large energy consumption and thus struggle with the trade‐off between water and energy, i.e., the water–energy nexus. In recent decades, the fast development of state‐of‐the‐art photothermal materials has injected new vitality into the field of freshwater production, which can effectively harness abundant and clean solar energy via the photothermal effect to fulfill the blue dream of low‐energy water purification/harvesting, so as to reconcile the water–energy nexus. Driven by the opportunities offered by photothermal materials, tremendous effort has been made to exploit diverse photothermal‐assisted water purification/harvesting technologies. At this stage, it is imperative and important to review the recent progress and shed light on the future trend in this multidisciplinary field. Here, a brief introduction of the fundamental mechanism and design principle of photothermal materials is presented, and the emerging photothermal applications such as photothermal‐assisted water evaporation, photothermal‐assisted membrane distillation, photothermal‐assisted crude oil cleanup, photothermal‐enhanced photocatalysis, and photothermal‐assisted water harvesting from air are summarized. Finally, the unsolved challenges and future perspectives in this field are emphasized. It is envisioned that this work will help arouse future research efforts to boost the development of solar‐driven low‐energy water purification/harvesting.

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