Salt Concentration-Regulated Desalination Mechanism Evolution in Battery Deionization for Freshwater

Wei, Wenfei; Feng, Xuezhen; Chen, Zhijie; Wang, Ranhao; Chen, Hong

2022-07-01

10.1021/acssuschemeng.2c00815

ACS Sustainable Chemistry & Engineering   Impact Factor & Quartile

2168-0485

Battery deionization (BDI) based on the Faradaic process featuring with large ion storage capacity and a high energy efficiency holds great prospects for the next-generation desalination application. Owing to the intrinsic salt ion insertion and the electrochemical redox nature of BDI, the ion insertion dynamics within the electrode during the electrochemical redox processes could be strongly influenced by the properties of the electrolyte, especially the salt concentration. Although tremendous effort has been devoted to developing the BDI electrode materials, the relationship between the detailed desalination dynamics and salt concentration in electrolytes has never been systematically studied since the invention of this technology. To unveil the underlying behaviors, we have employed the NaTi2(PO4)(3)@C electrode as the representative BDI electrode and systematically investigated the electrochemical desalination dynamics under different concentration NaCl solutions. For the first time, standard freshwater has been obtained from NaCl solution via the BDI technique. Interestingly, the intrinsic desalination mechanism evolves from a diffusion controlled charge contribution process into the capacitive charge contribution-dominated process as the NaCl concentration in water decreases from normal saline water into freshwater. The present study demonstrated the possibility of achieving freshwater with BDI. The insights obtained here on the ion storage dynamics paves the way for developing high-efficiency BDI electrodes toward practical desalination applications for freshwater.

battery deionization freshwater capacitive deionization Faradaic reactions desalination

SCI ; EI

English

First ; Corresponding

National Natural Science Foundation of China[21777045] ; Natural Science Funds for Distinguished Young Scholar of Guangdong Province, China[2020B151502094] ; Foundation of Shenzhen Science, Technology and Innovation Commission["J 2 0 1 9 0 8 0 9 1 4 4 4 0 9 4 6 0","JCYJ20200109141625078"]

Chemistry ; Science & Technology - Other Topics ; Engineering

Chemistry, Multidisciplinary ; Green & Sustainable Science & Technology ; Engineering, Chemical

WOS:000828007300001

AMER CHEMICAL SOC

20223412598622

Desalination ; Dynamics ; Electrochemical electrodes ; Energy efficiency ; Ions ; Saline water ; Sodium chloride

Water Resources:444 ; Water Treatment Techniques:445.1 ; Energy Conservation:525.2 ; Electric Batteries and Fuel Cells:702 ; Chemical Agents and Basic Industrial Chemicals:803 ; Chemical Products Generally:804

Web of Science

Southern Univ Sci & Technol, Sch Environm Sci & Engn, Shenzhen Key Lab Interfacial Sci & Engn Mat, State Environm Protect Key Lab Integrated Surface, Shenzhen 518055, Peoples R China

Wei, Wenfei,Feng, Xuezhen,Chen, Zhijie,et al. Salt Concentration-Regulated Desalination Mechanism Evolution in Battery Deionization for Freshwater[J]. ACS Sustainable Chemistry & Engineering,2022,10:9295-9302.

Wei, Wenfei,Feng, Xuezhen,Chen, Zhijie,Wang, Ranhao,&Chen, Hong.(2022).Salt Concentration-Regulated Desalination Mechanism Evolution in Battery Deionization for Freshwater.ACS Sustainable Chemistry & Engineering,10,9295-9302.

Wei, Wenfei,et al."Salt Concentration-Regulated Desalination Mechanism Evolution in Battery Deionization for Freshwater".ACS Sustainable Chemistry & Engineering 10(2022):9295-9302.