Plasmonic chemically modified cotton nanocomposite fibers for efficient solar water desalination and wastewater treatment

Kiriarachchi, Hiran D.; Awad, Fathi S.; Hassan, Amr; Bobb, Julian A.; Lin, Andrew; El‐Shall, M. Samy

doi:10.1039/c8nr05916k

Cited by 133 publications

(85 citation statements)

References 40 publications

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“…Meanwhile, the accumulated white salt crystals inevitably increase light reflection and reduce the light absorption of photothermal materials and increase the interface between the material and seawater, resulting in a significant decrease in evaporation efficiency over time. [ 30–32 ] Therefore, salt accumulation on photothermal materials is a crucial barrier to achieving long‐term, efficient, and stable SDID devices. Conventional methods to combat salt clogging include repeated washing or physical removal.…”

Section: Introductionmentioning

confidence: 99%

Salt Mitigation Strategies of Solar‐Driven Interfacial Desalination

Wang

et al. 2020

Adv Funct Materials

205

102

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Solar‐driven interfacial desalination (SDID), which is based on localized heating and interfacial evaporation, provides an opportunity for developing environmentally friendly and cost‐effective seawater thermal desalination. However, localized heating and rapidly generated interfacial steam may cause salt to accumulate on the evaporator's surface and block the channel of steam evaporation. Salt accumulation inevitably reduces the light absorption and service period of the solar absorber, resulting in a significant decrease in evaporation efficiency over time. Salt accumulation makes it difficult to produce SDID devices with high energy efficiency and long‐term stability for large‐scale use in remote poverty‐stricken areas. Therefore, the exploration of novel and effective strategies for addressing salt accumulation through both material design and structural engineering has attracted more attention in recent years. This review presents an overview of the state‐of‐the‐art advancements in salt‐resistant photothermal evaporation and discusses the critical issues for achieving salt mitigation SDID, focusing on the classification of salt mitigation strategies based on photothermal evaporation configurations, the basic mechanism of salt mitigation, and the architectural design of photothermal materials. Finally, the important challenges and prospects of SDID are discussed to providing a meaningful roadmap to efficient salt mitigation SDID.

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Section: Introductionmentioning

confidence: 99%

Salt Mitigation Strategies of Solar‐Driven Interfacial Desalination

Wang

et al. 2020

Adv Funct Materials

205

102

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“…Namely, bulk heating or localized plasma heating of metals, interfacial heating or non‐radiative semi‐conductor relaxation, and molecular thermal vibrations, based on various interaction mechanisms between electromagnetic radiation and matter. [ 4,6,13,14,16,17,19,29,58,61,73,91,92 ]…”

Section: Photothermal Conversion Mechanismsmentioning

confidence: 99%

Nanoenabled Photothermal Materials for Clean Water Production

2020

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Solar‐powered water evaporation is a primitive technology but interest has revived in the last five years due to the use of nanoenabled photothermal absorbers. The cutting‐edge nanoenabled photothermal materials can exploit a full spectrum of solar radiation with exceptionally high photothermal conversion efficiency. Additionally, photothermal design through heat management and the hierarchy of smooth water‐flow channels have evolved in parallel. Indeed, the integration of all desirable functions into one photothermal layer remains an essential challenge for an effective yield of clean water in remote‐sensing areas. Some nanoenabled photothermal prototypes equipped with unprecedented water evaporation rates have been reported recently for clean water production. Many barriers and difficulties remain, despite the latest scientific and practical implementation developments. This Review seeks to inspire nanoenvironmental research communities to drive onward toward real‐time solar‐driven clean water production.

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“…The conventional bulk-heating approach, therefore, leads to large amount of heat loss to the unevaporated part of water [64,68]. Bulk heating introduces a large lag and response time because of its large thermal inertia [63,64,69], but surface evaporation has minimal thermal inertia and responds very quickly to the change in the energy input, and allows for tighter process control for water quality and reducing energy consumption [64,68,330]. However, developing materials for long-term solar desalination through heat localization remains an open challenge due to fouling of the structure after a short period of time [64,68,269].…”

Section: Capillary-driven Desalinationmentioning

confidence: 99%

Looking Beyond Energy Efficiency: An Applied Review of Water Desalination Technologies and an Introduction to Capillary-Driven Desalination

Ahmadvand

Abbasi

Azarfar

et al. 2019

Water

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Most notable emerging water desalination technologies and related publications, as examined by the authors, investigate opportunities to increase energy efficiency of the process. In this paper, the authors reason that improving energy efficiency is only one route to produce more cost-effective potable water with fewer emissions. In fact, the grade of energy that is used to desalinate water plays an equally important role in its economic viability and overall emission reduction. This paper provides a critical review of desalination strategies with emphasis on means of using low-grade energy rather than solely focusing on reaching the thermodynamic energy limit. Herein, it is argued that large-scale commercial desalination technologies have by-and-large reached their engineering potential. They are now mostly limited by the fundamental process design rather than process optimization, which has very limited room for improvement without foundational change to the process itself. The conventional approach toward more energy efficient water desalination is to shift from thermal technologies to reverse osmosis (RO). However, RO suffers from three fundamental issues: (1) it is very sensitive to high-salinity water, (2) it is not suitable for zero liquid discharge and is therefore environmentally challenging, and (3) it is not compatible with low-grade energy. From extensive research and review of existing commercial and lab-scale technologies, the authors propose that a fundamental shift is needed to make water desalination more affordable and economical. Future directions may include novel ideas such as taking advantage of energy localization, surficial/interfacial evaporation, and capillary action. Here, some emerging technologies are discussed along with the viability of incorporating low-grade energy and its economic consequences. Finally, a new process is discussed and characterized for water desalination driven by capillary action. The latter has great significance for using low-grade energy and its substantial potential to generate salinity/blue energy.

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Plasmonic chemically modified cotton nanocomposite fibers for efficient solar water desalination and wastewater treatment

Cited by 133 publications

References 40 publications

Salt Mitigation Strategies of Solar‐Driven Interfacial Desalination

Salt Mitigation Strategies of Solar‐Driven Interfacial Desalination

Nanoenabled Photothermal Materials for Clean Water Production

Looking Beyond Energy Efficiency: An Applied Review of Water Desalination Technologies and an Introduction to Capillary-Driven Desalination

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