Review of the current state of technology for capacitive deionization of aqueous salt solutions

IF 0.3 Q4 PHYSICS, MULTIDISCIPLINARY

Bulletin of the University of Karaganda-Physics Pub Date : 2023-09-30 DOI:10.31489/2023ph3/16-33

A. Zakharov, A. Tukesheva, V. Pavlenko, Syed Fahad Bin Haque, John Ferraris, A. Zakhidov, T. Tazhibayeva, T. Bazarbayeva

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Abstract

The availability of clean water at affordable prices is one of the key technological, social, and economic challenges of the 21st century. The increased extraction of groundwater worldwide is leading to the gradual intrusion of salty water into sources and water horizons. In order to use this water for industrial and agricultural purposes, or as drinking water, it needs to be purified and desalinated. Thus, methods of desalinating water of different salinity levels, ranging from brackish to seawater, are becoming more prominent. The overall goal of current research is to make water desalination technologies more energyefficient and cost-effective. One promising technology that meets these requirements is capacitive deionization (CDI) of water. This technology has been widely known for over 30 years, but significant progress in CDI research has only been achieved in recent years. In this review, we examine the currently developed architectures of CDI cells, advancements in carbon materials, and discuss the prospects and challenges of commercializing this technology.

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盐水溶液电容性去离子技术现状综述

以可承受的价格获得清洁水是21世纪主要的技术、社会和经济挑战之一。世界范围内地下水开采的增加导致咸水逐渐侵入水源和水界。为了将这些水用于工业和农业目的，或作为饮用水，需要对其进行净化和脱盐。因此，淡化从微咸水到海水等不同含盐量的水的方法正变得越来越突出。目前研究的总体目标是使海水淡化技术更加节能和经济。满足这些要求的一项有前途的技术是水的电容去离子(CDI)。这项技术已经广为人知30多年，但CDI研究直到最近几年才取得重大进展。在这篇综述中，我们研究了目前开发的CDI电池结构，碳材料的进展，并讨论了该技术商业化的前景和挑战。

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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Bulletin of the University of Karaganda-Physics PHYSICS, MULTIDISCIPLINARY-

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