標題: Sustainable Desalination by 3:1 Reduced Graphene Oxide/Titanium Dioxide Nanotubes (rGO/TiONTs) Composite via Capacitive Deionization at Different Sodium Chloride Concentrations
作者: Lazarte, John Paolo L.
Bautista-Patacsil, Liza
Eusebio, Ramon Christian P.
Orbecido, Aileen H.
Doong, Ruey-an
環境工程研究所
Institute of Environmental Engineering
關鍵字: reduced graphene oxide;titanium dioxide nanotubes;sodium chloride;sustainable desalination;capacitive deionization
公開日期: 1-Sep-2019
摘要: The capability of novel 3:1 reduced graphene oxide/titanium dioxide nanotubes (rGO/TiONTs) composite to desalinate using capacitive deionization (CDI) employing highly concentrated NaCl solutions was tested in this study. Parameters such as material wettability, electrosorption capacity, charge efficiency, energy consumption, and charge-discharge retention were tested at different NaCl initial concentrations-100 ppm, 2000 ppm, 15,000 ppm, and 30,000 ppm. The rGO/TiONTs composite showed good material wettability before and after CDI runs with its contact angles equal to 52.11 degrees and 56.07 degrees, respectively. Its two-hour electrosorption capacity during CDI at 30,000 ppm NaCl influent increased 1.34-fold compared to 100 ppm initial NaCl influent with energy consumption constant at 1.11 kWh per kg with NaCl removed. However, the percentage discharge (concentration-independent) at zero-voltage ranged from 4.9-7.27% only after 30 min of desorption. Repeated charge/discharge at different amperes showed that the slowest charging rate of 0.1 Ag-1 had the highest charging time retention at 60% after 100 cycles. Increased concentration likewise increases charging time retention. With this consistent performance of a CDI system utilizing rGO/TiONTs composite, even at 30,000 ppm and 100 cycles, it can be a sustainable alternative desalination technology, especially if a low charging current with reverse voltage discharge is set for a longer operation.
URI: http://dx.doi.org/10.3390/nano9091319
http://hdl.handle.net/11536/153118
DOI: 10.3390/nano9091319
期刊: NANOMATERIALS
Volume: 9
Issue: 9
起始頁: 0
結束頁: 0
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