Membrane-Current Collector-Based Flow-Electrode Capacitive Deionization System: A Novel Stack Configuration for Scale-Up Desalination

Zhou

et al. 2022

ACS EST Eng.

As an emerging desalination technology, flow-electrode capacitive deionization (FCDI) has aroused extensive attraction due to its advantage of pseudoinfinite adsorption capacity. However, some problems still remain in the traditional FCDI devices, i.e., its streaming and seeping quality which has severely limited the progress. Herein, some improvements were achieved by changing the direction of saline water in spacer. Furthermore, the Archimedes spiral flow channel model was introduced to improve the flow behavior of carbon slurry in the FCDI unit cell for the first time, which has vastly boosted the desalination performance of FCDI devices. The computational fluid dynamics (CFD) simulation revealed the more uniform velocity distribution and longer residence time of carbon slurry in spiral flow channels to enhance the desalination, while the flow rate of carbon slurry in a straight line is faster but slower in the corner of serpentine flow channels, causing a negative effect on the desalination performance. After long-term continuous desalination in 3.5 g L–1 NaCl solution at 2.4 V, 99.88% of salt removal efficiency was achieved with a superior salt removal rate of 4.06 μmol cm–2 min–1 and 98.9% charge efficiency for the spiral flow channel FCDI device, demonstrating a stable desalination performance.

Section: Resultsmentioning

confidence: 99%

Enhanced Desalination Performance by a Novel Archimedes Spiral Flow Channel for Flow-Electrode Capacitive Deionization

Zhou

et al. 2022

ACS EST Eng.

“…Electro-assisted adsorption has attracted increasing attention due to its distinct benets such as efficient performance, rapid reaction, and environmental friendliness, making it a promising technology for pollutants elimination. [8][9][10][11] In the electrosorption process, charged ions can be rapidly adsorbed and stored in the oppositely charged electrode when an external voltage is applied. 12 Compared to conventional adsorption, phosphate anions are able to migrate faster and reach deeper adsorptive sites with the assistance of the electric driving force.…”

Section: Introductionmentioning

confidence: 99%

Engineering bimetallic capture sites on hierarchically porous carbon electrode for efficient phosphate electrosorption: multiple active centers and excellent electrochemical properties

et al. 2023

J. Mater. Chem. A

“…Electroadsorption has been widely studied because of its low energy consumption, − particularly flow electrode capacitive deionization (FCDI). − FCDI overcomes the problems of low adsorption capacity and noncontinuous operation of traditional capacitive deionization (CDI). ,, The working principle of FCDI is similar to that of CDI, and ion removal is mainly realized by the electric double layer formed by the flow electrodes. − Therefore, many researchers have focused on the development of high-performance flow electrodes, including capacitive materials (activated carbon, , carbon nanotubes, − carbon black, , and improved carbon-based materials − ) and redox materials (vanadium, hydroquinone, and BTMAP-Fc). Due to the low price and stable performance, powdered activated carbon (PAC) has become the main material for FCDI flow electrodes. − Therefore, further optimization of the desalination performance of PAC has become a major problem at the present stage. The premise is to understand the influence of the physicochemical properties of PAC on the desalination performance of FCDI, particularly to determine the key factors.…”

Section: Introductionmentioning

confidence: 99%

Electron Transfer of Activated Carbon to Anode Excites and Regulates Desalination in Flow Electrode Capacitive Deionization

Wang

et al. 2023

Environ. Sci. Technol.

The desalination performance of flow electrode capacitive deionization (FCDI) is determined by the ion adsorption on the powdered activated carbon (PAC) and the electron transfer between the current collector and PAC. However, a comprehensive understanding of rate-limiting steps is lacking, let alone to enhance FCDI desalination by regulating the PAC characteristics. This study showed that the electron transfer between PAC and the current collector on the anode side was the rate-limiting step of FCDI desalination. Compared with W900, the desalination performance of FCDI decreased by 95% when W1200 with weak electron transfer ability was used as a flow electrode. The PAC selected in this study transferred electrons directly through the conductive carbon matrix in FCDI and was mainly affected by graphitization. The desalination performance of FCDI was improved by 20 times when the graphitization degree of PAC increased from 0.69 to 1.03. The minimum energy required for electrons to escape from the PAC surface was reduced by the high degree of graphitization, from 4.27 to 3.52 eV, thus improving the electron transfer capacity of PAC on the anode side. This study provides a direction for the optimization of flow electrodes and further promotes the development of FCDI.