Redox flow cells for energy conversion

León, Carlos Ponce de; Frías-Ferrer, Á.; González-Garcı́a, José; Szánto, D.A.; Walsh, Frank C.

doi:10.1016/j.jpowsour.2006.02.095

Cited by 1,042 publications

(708 citation statements)

References 47 publications

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“…Also, this system shows a longer cycle life of 7,000 cycles compared with 4,500 cycles for NAS batteries and the energy efficiency of the BPOE is B80% (Fig. 6b), which is comparable to 85% of NAS batteries 8 , and higher than B70% of redox-flow batteries 55 , but the self-discharge characteristic of the NAS and sodium-ion batteries based on the intercalation mechanism are better than for the BPOE electrodes ( Supplementary Fig. S8).…”

Section: Discussionmentioning

confidence: 80%

Aromatic porous-honeycomb electrodes for a sodium-organic energy storage device

et al. 2013

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Rechargeable batteries using organic electrodes and sodium as a charge carrier can be highperformance, affordable energy storage devices due to the abundance of both sodium and organic materials. However, only few organic materials have been found to be active in sodium battery systems. Here we report a high-performance sodium-based energy storage device using a bipolar porous organic electrode constituted of aromatic rings in a porous-honeycomb structure. Unlike typical organic electrodes in sodium battery systems, the bipolar porous organic electrode has a high specific power of 10 kW kg À 1 , specific energy of 500 Wh kg À 1 , and over 7,000 cycle life retaining 80% of its initial capacity in half-cells. The use of bipolar porous organic electrode in a sodium-organic energy storage device would significantly enhance cost-effectiveness, and reduce the dependency on limited natural resources. The present findings suggest that bipolar porous organic electrode provides a new material platform for the development of a rechargeable energy storage technology.

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Section: Discussionmentioning

confidence: 80%

Aromatic porous-honeycomb electrodes for a sodium-organic energy storage device

et al. 2013

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“…RFBs are currently attracting particular attention due to their simplicity and ability to store large amounts of energy [1,2]. In RFBs, dissolved redox species are stored in tanks and pumped to an electrochemical cell during discharging and charging.…”

Section: Introductionmentioning

confidence: 99%

Room temperature ionic liquid electrolytes for redox flow batteries

Ejigu

Greatorex-Davies

Walsh

2015

Electrochemistry Communications

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“…in combination with the Zn(II)/Zn(0) couple, is used in redox flow batteries and the performance can be monitored with an ORP probe (Ponce de Leo´n et al, 2006). The cell voltage of the Zn/Ce system during charge is approximately 2.5 V and drops below 2 V on discharge.…”

Section: Article In Pressmentioning

confidence: 99%

The use of electrolyte redox potential to monitor the Ce(IV)/Ce(III) couple

Trinidad

León

Walsh

2008

Journal of Environmental Management

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Mathematical modelling of the oxidation reduction redox potential (ORP) of an electrolyte has been carried out for a batch system comprising an electrochemical reactor and an electrolyte circuit containing a redox couple. The ORP can be useful to monitor the environmental impact of chemical species in solution that represent a risk to the environment. Considerations of four fundamental equations, namely, the Nernst equation, a mass balance, Faraday's laws of electrolysis and a first order kinetic equation, leads to an expression for the electrolyte redox potential as a function of the batch time, the electrical charge and the redox concentration. Such an expression facilitates graphical plots which can be used to estimate kinetic parameters, current efficiency and the relative redox concentration. The Ce(IV)/Ce(III) system has been chosen as a model reaction for electrolyte redox potential measurement in a batch recycle system consisting of a pumped flow through a divided FM01-LC parallel-plate electrochemical reactor (64 cm 2 projected electrode area) and a well mixed tank (3600 cm 3 ). The differences between experimental and model predictions are discussed. r

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Redox flow cells for energy conversion

Cited by 1,042 publications

References 47 publications

Aromatic porous-honeycomb electrodes for a sodium-organic energy storage device

Aromatic porous-honeycomb electrodes for a sodium-organic energy storage device

Room temperature ionic liquid electrolytes for redox flow batteries

The use of electrolyte redox potential to monitor the Ce(IV)/Ce(III) couple

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