Improved Desalination Performance of Flow- and Fixed-Capacitive Deionization using Redox-Active Quinone

Tran, Nguyen Anh Thu; Phuoc, Ngo Minh; Yoon, Ho Kyoung; Jung, Euiyeon; Lee, Young-Woo; Kang, Beom‐Goo; Kang, Hyeonbae; Yoo, Chung‐Yul; Cho, Younghyun

doi:10.1021/acssuschemeng.0c06651

Cited by 35 publications

(21 citation statements)

References 52 publications

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“…1). 43–45,47–54 Using a saline electrolyte can increase the electrodes' salt adsorption capacities and/or salt adsorption rates relative to those achieved in MCDI cells, while potentially decreasing deionization energy demands. 43,47 Recirculating the electrolyte and flowing it over both electrodes can also facilitate continuous cell operation.…”

Section: Introductionmentioning

confidence: 99%

“…43,47 Recirculating the electrolyte and flowing it over both electrodes can also facilitate continuous cell operation. 44,49–54 In some cases, the addition of a soluble redox-active compound to the electrolyte decreased energy demands. 49,52 Note that systems using suspended carbon particles or a soluble redox-active compound in a recirculated electrolyte begin to, or do, resemble ED cells, as salt is stored in the electrolyte, not at or in the electrode.…”

Section: Introductionmentioning

confidence: 99%

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Comparing energy demands and longevities of membrane-based capacitive deionization architectures

Pothanamkandathil

Gorski

2022

Environ. Sci.: Water Res. Technol.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Comparing energy demands and longevities of membrane-based capacitive deionization architectures

Pothanamkandathil

Gorski

2022

Environ. Sci.: Water Res. Technol.

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“…Electron-mediators are another popular conductive additive which rely on fast and reversible redox reactions occurring at the electrode/electrolyte and current collector/electrolyte interfaces in order to accelerate electron transport between the active materials and the current collectors (Figure d). Most of these compounds possess proton-coupled multielectron exchange ability and prefer basic (PPD and MPD) or acidic (H 2 Q) conditions to facilitate electron/proton transfer. − Carbon slurry containing PPD in an alkaline environment exhibited a 130% increase in capacitance and 75% reduction in ohmic resistance compared to those of the pristine carbon slurries at neutral pH . In other work by Ma et al, facile redox transformation between hydroquinone (H 2 Q)/benzoquinone (Q) (eq ) within the slurry electrodes significantly accelerated the electron and ionic transfer, boosting the average salt removal rate by 131% (Figure d).…”

Section: Fcdi Designs and Operational Modesmentioning

confidence: 99%

Flow Electrode Capacitive Deionization (FCDI): Recent Developments, Environmental Applications, and Future Perspectives

Zhang

Lei

et al. 2021

Environ. Sci. Technol.

182

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With the increasing severity of global water scarcity, a myriad of scientific activities is directed toward advancing brackish water desalination and wastewater remediation technologies. Flow-electrode capacitive deionization (FCDI), a newly developed electrochemically driven ion removal approach combining ion-exchange membranes and flowable particle electrodes, has been actively explored over the past seven years, driven by the possibility of energy-efficient, sustainable, and fully continuous production of high-quality fresh water, as well as flexible management of the particle electrodes and concentrate stream. Here, we provide a comprehensive overview of current advances of this interesting technology with particular attention given to FCDI principles, designs (including cell architecture and electrode and separator options), operational modes (including approaches to management of the flowable electrodes), characterizations and modeling, and environmental applications (including water desalination, resource recovery, and contaminant abatement). Furthermore, we introduce the definitions and performance metrics that should be used so that fair assessments and comparisons can be made between different systems and separation conditions. We then highlight the most pressing challenges (i.e., operation and capital cost, scale-up, and commercialization) in the full-scale application of this technology. We conclude this state-of-the-art review by considering the overall outlook of the technology and discussing areas requiring particular attention in the future.

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“…Most of the faradaic electrode materials used in HCDI systems were inorganic compounds, which have several drawbacks, such as decomposition and dissolution, which limit the cycling performance of the system. Therefore, researchers have coupled these faradaic inorganic compounds with organic components or even replaced them with redox-active polymers to reinforce the structural stability of the electrode and enhance the long-term stability of HCDI. − …”

Section: Hcdi Systemmentioning

confidence: 99%

Recent Advances in Faradic Electrochemical Deionization: System Architectures versus Electrode Materials

et al. 2021

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Capacitive deionization (CDI) is an energy-efficient desalination technique. However, the maximum desalination capacity of conventional carbon-based CDI systems is approximately 20 mg g–1, which is too low for practical applications. Therefore, the focus of research on CDI has shifted to the development of faradic electrochemical deionization systems using electrodes based on faradic materials which have a significantly higher ion-storage capacity than carbon-based electrodes. In addition to the common symmetrical CDI system, there has also been extensive research on innovative systems to maximize the performance of faradic electrode materials. Research has focused primarily on faradic reactions and faradic electrode materials. However, the correlation between faradic electrode materials and the various electrochemical deionization system architectures, i.e., hybrid capacitive deionization, rocking-chair capacitive deionization, and dual-ion intercalation electrochemical desalination, remains relatively unexplored. This has inhibited the design of specific faradic electrode materials based on the characteristics of individual faradic electrochemical desalination systems. In this review, we have characterized faradic electrode materials based on both their material category and the electrochemical desalination system in which they were utilized. We expect that the detailed analysis of the properties, advantages, and challenges of the individual systems will establish a fundamental correlation between CDI systems and electrode materials that will facilitate future developments in this field.

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Improved Desalination Performance of Flow- and Fixed-Capacitive Deionization using Redox-Active Quinone

Cited by 35 publications

References 52 publications

Comparing energy demands and longevities of membrane-based capacitive deionization architectures

Comparing energy demands and longevities of membrane-based capacitive deionization architectures

Flow Electrode Capacitive Deionization (FCDI): Recent Developments, Environmental Applications, and Future Perspectives

Recent Advances in Faradic Electrochemical Deionization: System Architectures versus Electrode Materials

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