Double Layer Graphene Oxide Loaded With Propylammonium Nitrate for Selective Adsorption of Inorganic Salts

Proceedings of the 7th World Congress on Recent Advances in Nanotechnology Pub Date : 2022-04-01 DOI:10.11159/icnnfc22.147

H. Abukhalifeh, I. Alnashef, B. Zhuman, I. Zuburtikudis

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引用次数: 1

Abstract

- Due to freshwater scarcity, desalination process gains more importance. Developing a green and environmentally friendly solution for extraction of the salts from the seawater becomes a major challenge nowadays. Among all desalination processes, membrane desalination is widely used. About 80 % of total desalination plants are based on reverse osmosis (RO) worldwide. However, RO desalination is considered to be costly owing to the short lifetime of the membranes and high replacement costs. Membrane fouling is one of the main causes of this limitation. Membrane inorganic fouling can be easily affected by calcium and magnesium inorganic salts. Hence, it is important to develop an efficient adsorbent used in RO pre-treatment processes to address the problem of inorganic fouling. The great advantages offered by nanomaterials and green solvents allow the creation of new functional materials for inorganic salt adsorption. Ionic liquids (ILs) comprising of an organic cation and an organic or inorganic anion, exhibit superior characteristics and are used widely for different applications, including separation and extraction processes of salts and of several heavy metals in the seawater. However, ILs which have good solubility of inorganic salts are mostly hydrophilic. Therefore, cross-contamination of the pre-treatment water during the extraction process can occur. However, if ILs are supported on carbon nanostructures (CNS), as graphene oxide (GO) or other types of CNS, this can be avoided. As a result, this will reduce the operational costs of the plants by decreasing the amount of inorganic fouling in the membranes. Experimental findings showed that GO modified with IL can successfully adsorb CaCl 2 , MgCl 2 and NaCl salts. Physical functionalization has been confirmed using thermal gravimetric analysis (TGA) and Raman Spectroscopy analysis. Moreover, leaching of IL from GO has been studied using Total Organic Carbon (TOC).

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硝酸丙铵负载双层氧化石墨烯对无机盐的选择性吸附

-由于淡水稀缺，海水淡化过程变得更加重要。开发一种绿色环保的从海水中提取盐分的解决方案成为当今的主要挑战。在所有的脱盐工艺中，膜脱盐是应用最广泛的。全世界大约80%的海水淡化厂是基于反渗透(RO)的。然而，由于膜的使用寿命短，更换成本高，反渗透海水淡化被认为是昂贵的。膜污染是造成这种限制的主要原因之一。膜无机污染容易受到钙镁无机盐的影响。因此，开发一种高效的吸附剂用于反渗透预处理过程，以解决无机污染问题是很重要的。纳米材料和绿色溶剂的巨大优势使无机盐吸附的新功能材料得以创造。离子液体(ILs)由有机阳离子和有机或无机阴离子组成，具有优越的特性，广泛用于不同的应用，包括盐和海水中几种重金属的分离和提取过程。而对无机盐具有良好溶解度的il，大多是亲水的。因此，在萃取过程中可能会发生预处理水的交叉污染。然而，如果il被支持在碳纳米结构(CNS)上，如氧化石墨烯(GO)或其他类型的CNS，则可以避免这种情况。因此，这将通过减少膜中的无机污染量来降低工厂的运营成本。实验结果表明，经IL修饰的氧化石墨烯能够成功吸附cacl2、MgCl 2和NaCl盐。用热重分析(TGA)和拉曼光谱分析证实了其物理官能化。此外，利用总有机碳(TOC)研究了氧化石墨烯中IL的浸出。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings of the 7th World Congress on Recent Advances in Nanotechnology

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