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1. Properties of amorphous iron phosphate in pseudocapacitive sodium ion removal for water desalination

   https://doi.org/10.1039/D0RA02010A  

   Bentalib, Abdulaziz ; Pan, Yanbo ; Yao, Libo ; Peng, Zhenmeng ( April 2020 , RSC Advances)

   Capacitive deionization (CDI) is an energy saving and environmentally friendly technology for water desalination. However, classical CDI is challenged by a low salt removal capacity. To improve the desalination capacity, electrode materials utilizing the battery mechanism for salt ion removal have emerged as a new direction more recently. In this work, we report a study of amorphous iron phosphate (FePO 4 ) as a promising electrode material for pseudocapacitive sodium ion removal. Sodium ions can be effectively, reversibly intercalated and de-intercalated upon its electrochemical reduction and oxidation, with an excellent sodium ion capacity under half-cell testing conditions. By assembling a hybrid CDI (HCDI) system utilizing the FePO 4 electrode for pseudocapacitive sodium ion removal and active carbon electrode for capacitive chloride ion removal, the cell exhibited a high salt removal capacity and good reversibility and durability, which was attributed to the advantageous features of amorphous FePO 4 . The HCDI system achieved a high deionization capacity (82 mg g −1 ) in 10 mM NaCl, a fast deionization rate (0.046 mg g −1 s −1 ), and good stability and cyclability. 

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2. Capacitive deionization and electrosorption for heavy metal removal

   https://doi.org/10.1039/C9EW00945K  

   Chen, Raylin ; Sheehan, Thomas ; Ng, Jing Lian ; Brucks, Matthew ; Su, Xiao ( February 2020 , Environmental Science: Water Research & Technology)

   Capacitive deionization (CDI) technologies have gained intense attention for water purification and desalination in recent years. Inexpensive and widely available porous carbon materials have enabled the fast growth of electrosorption research, highlighting the promise of CDI as a potentially cost-effective technology to remove ions. Whereas the main focus of CDI has been on bulk desalination, there has been a recent shift towards electrosorption for selective ion separations. Heavy metals are pollutants that can have severe health impacts and are present in both industrial wastewater and groundwater leachates. Heavy metal ions, such as chromium, cadmium, or arsenic, are of great concern to traditional treatment technologies, due to their low concentration and the presence of competing species. The modification/functionalization of porous carbon and recent developments of faradaic and redox-active materials have offered a new avenue for selective ion-binding of heavy metal contaminants. Here, we review the progress in electrosorptive technologies for heavy metal separations. We provide an overview of the wide applicability of carbon-based electrodes for heavy metal removal. In parallel, we highlight the trend toward modification of carbon materials, new developments in faradaic interfaces, and the underlying physico-chemical mechanisms that promote selective heavy metal separations. 

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3. Engineering Carbon Nanotube Forest Superstructure for Robust Thermal Desalination Membranes

   https://doi.org/10.1002/adfm.201903125  

   Sun, Meng ; Boo, Chanhee ; Shi, Wenbo ; Rolf, Julianne ; Shaulsky, Evyatar ; Cheng, Wei ; Plata, Desiree L. ; Qu, Jiuhui ; Elimelech, Menachem ( June 2019 , Advanced Functional Materials)

   Desalination by membrane distillation (MD) using low‐grade or waste heat provides a potential route for sustainable water supply. Nonwetting, porous membranes that provide a selective pathway for water vapor over nonvolatile salt are at the core of MD desalination. Conventional water‐repelling MD membranes (i.e., hydrophobic and superhydrophobic membranes) fail to ensure long‐term desalination performance due to pore wetting and surface fouling. To address these challenges, a defect‐free carbon nanotube forest (CNTF) is engineered in situ on a porous electrospun silica fiber substrate. The engineered CNTF forms an ultrarough and porous interface structure, allowing outstanding wetting resistance against water in air and oil underwater. As a result of this antiwetting property, the composite CNTF membrane displays a stable water vapor flux and a near complete salt rejection (>99.9%) in the desalination of highly saline water containing low surface tension contaminants. The antimicrobial property of the composite CNTF membrane imparted by the unique forest‐like architecture and the oxidative effect of carbon nanotubes (CNTs) are further demonstrated. The results exemplify an effective strategy for engineering CNT architecture to elucidate the structure–property–performance relationship of the nanocomposite membranes and to guide the design of robust thermal desalination membranes.

    

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4. Ionic liquid enables highly efficient low temperature desalination by directional solvent extraction

   https://doi.org/10.1038/s41467-020-20706-y  

   Guo, Jiaji ; Tucker, Zachary D. ; Wang, Yu ; Ashfeld, Brandon L. ; Luo, Tengfei ( January 2021 , Nature Communications)

   Seawater desalination plays a critical role in addressing the global water shortage challenge. Directional Solvent Extraction (DSE) is an emerging non-membrane desalination technology that features the ability to utilize very low temperature waste heat (as low as 40 °C). This is enabled by the subtly balanced solubility properties of directional solvents, which do not dissolve in water but can dissolve water and reject salt ions. However, the low water yield of the state-of-the-art directional solvent (decanoic acid) significantly limits its throughput and energy efficiency. In this paper, we demonstrate that by using ionic liquid as a new directional solvent, saline water can be desalinated with much higher production rate and thus significantly lower the energy and exergy consumptions. The ionic liquid identified suitable for DSE is [emim][Tf₂N], which has a much (~10×) higher water yield than the currently used decanoic acid. Using molecular dynamics simulations with Gibbs free energy calculations, we reveal that water dissolving in [emim][Tf₂N] is energetically favorable, but it takes significant energy for [emim][Tf₂N] ions to dissolve in water. Our findings may significantly advance the DSE technology as a solution to the challenges in the global water-energy nexus.

    

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5. Forest waste to clean water: natural leaf-guar-derived solar desalinator

   https://doi.org/10.1039/D1NR04883J  

   Caratenuto, Andrew ; Aljwirah, Abdulrahman ; Tian, Yanpei ; Liu, Xiaojie ; Wan, Yinsheng ; Zheng, Yi ( November 2021 , Nanoscale)

   Water scarcity and waste mismanagement are global crises that threaten the health of populations worldwide and a sustainable future. In order to help mitigate both these issues, a solar desalination device composed entirely of fallen leaves and guar – both natural materials – has been developed and demonstrated herein. This sustainable desalinator realizes an evaporation rate of 2.53 kg m −2 h −1 under 1 sun irradiance, and achieves consistent performance over an extended exposure period. Furthermore, it functions efficiently under a variety of solar intensities and in high salinity environments, and can produce water at salinities well within the acceptable levels for human consumption. Such strong performance in a large variety of environmental conditions is made possible by its excellent solar absorption, superb and rapid water absorption, low thermal conductivity, and considerable salt rejection abilities. Composed primarily of biowaste material and boasting a simple fabrication process, this leaf-guar desalinator provides a low-cost and sustainable avenue for alleviating water scarcity and supporting a green path forward. 

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