Preparation and electrosorption desalination performance of activated carbon electrode with titania

Abstract The activated carbon (AC) electrode was prepared and carbonized at 850 °C for electrosorption desalination. As a result, the electrical double-layer capacitance of AC electrode was improved by 2.16 times by carbonization. In order to improve the desalination performance of AC electrode, it was modified by loading titania with sol-gel method. The electrodes were analyzed using scanning electron microscope (SEM), X-ray fluorescence (XRF), X-ray diffraction (XRD) and electrochemical workstation. The results revealed that there was a certain amount of titania on the surface of modified AC electrode, which was accumulated on the surface of electrode forming some flocculent substance and its crystalline phase was rutile. After modification, the forming rate of electrical double-layer and electrosorption capacity of AC electrode were obviously improved and its desalination ratio was increased by 62.7%, whereas physical adsorption was decreased. In addition, compared with AC electrode, activated carbon fiber (ACF) electrode, and carbon nanotube (CNT) electrode, the AC loaded titania (AC-TiO 2 ) electrode exhibited relatively higher desalination and desorption ratios as well as a reasonable cost. Therefore, the AC-TiO 2 electrode would be suitable for the application of electrosorption desalination in the practical industry.

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