A chemistry and material perspective on lithium redox flow batteries towards high-density electrical energy storage

Zhao, Yu; Ding, Yu; Li, Yutao; Peng, Lele; Byon, Hye Ryung; Goodenough, John B; Yu, Guihua

doi:10.1039/c5cs00289c

Cited by 400 publications

(260 citation statements)

References 277 publications

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“…Any wearable device requires energy for operation, and a storage device is necessary to supply this energy. There have been tremendous advancements in the field of energy conversion and storage devices in the past few years 192, 193, 194, 195, 196, 197, 198, 199, 200, 201, 202, 203, 204, 205, 206, 207, 208, 209, 210, 211, 212, 213, 214, 215, 216, 217, 218. A combination of thin and flexible energy harvesting device and a portable storage device remains the best option for powering the wearable devices.…”

Section: Self‐reliant Energy Systems For Wearablesmentioning

confidence: 99%

Fiber‐Type Solar Cells, Nanogenerators, Batteries, and Supercapacitors for Wearable Applications

et al. 2018

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Wearable electronic devices represent a paradigm change in consumer electronics, on‐body sensing, artificial skins, and wearable communication and entertainment. Because all these electronic devices require energy to operate, wearable energy systems are an integral part of wearable devices. Essentially, the electrodes and other components present in these energy devices should be mechanically strong, flexible, lightweight, and comfortable to the user. Presented here is a critical review of those materials and devices developed for energy conversion and storage applications with an objective to be used in wearable devices. The focus is mainly on the advances made in the field of solar cells, triboelectric generators, Li‐ion batteries, and supercapacitors for wearable device development. As these devices need to be attached/integrated with the fabric, the discussion is limited to devices made in the form of ribbons, filaments, and fibers. Some of the important challenges and future directions to be pursued are also highlighted.

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Section: Self‐reliant Energy Systems For Wearablesmentioning

confidence: 99%

Fiber‐Type Solar Cells, Nanogenerators, Batteries, and Supercapacitors for Wearable Applications

et al. 2018

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“…59 ). 65 The lower the energy density, the greater the size of the storage tank needed to meet a specific energy requirement. The tank footprint is not necessarily an issue in stationary energy storage, but it makes it challenging for RFBs to penetrate other applications such as transportation, and even within stationary storage applications, the footprint is particularly important where space involves a cost and access premium such as in urban environments.…”

Section: à2mentioning

confidence: 99%

“…75 More comprehensive discussions on organic and/or Li-based RFBs can be found in these recent reviews. 19,22,65,67,76 The second limitation, electroactive material solubility, is a challenge for both aqueous and organic RFBs. The higher the concentration of redox compounds in the electrolyte, the greater the number of electrons that can be exchanged for a given volume or mass of electrolyte and hence the higher the capacity and energy density of the RFB.…”

Section: à2mentioning

confidence: 99%

“…22,73 The voltage has even been reported as high as $3.5 V when paired with a Li metal anode. 65,74 There have also been efforts to construct hybrid organic-aqueous RFBs to take advantage of the low potential achievable at the anode due to the organic electrolyte and suitable potential and high ionic conductivity offered by the aqueous electrolyte on the cathode side. 75 More comprehensive discussions on organic and/or Li-based RFBs can be found in these recent reviews.…”

Section: à2mentioning

confidence: 99%

“…17,64 A few recent reviews provide good discussions on conventional RFBs. 14,19,22,59,[65][66][67] Efforts to improve the performance of RFBs for next generation concepts have largely been focused on improving RFB energy density. RFB energy density is determined by the energy density of the electrolytes, which is relatively low compared to other battery technologies.…”

Section: à2mentioning

confidence: 99%

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Review Article: Flow battery systems with solid electroactive materials

Koenig

2017

Journal of Vacuum Science &Amp; Technology B, Nanotechnology and Microelectronics: Materials, Processing, Measurement, and Phen

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Energy storage is increasingly important for a diversity of applications. Batteries can be used to store solar or wind energy providing power when the Sun is not shining or wind speed is insufficient to meet power demands. For large scale energy storage, solutions that are both economically and environmentally friendly are limited. Flow batteries are a type of battery technology which is not as well-known as the types of batteries used for consumer electronics, but they provide potential opportunities for large scale energy storage. These batteries have electrochemical recharging capabilities without emissions as is the case for other rechargeable battery technologies; however, with flow batteries, the power and energy are decoupled which is more similar to the operation of fuel cells. This decoupling provides the flexibility of independently designing the power output unit and energy storage unit, which can provide cost and time advantages and simplify future upgrades to the battery systems. One major challenge of the existing commercial flow battery technologies is their limited energy density due to the solubility limits of the electroactive species. Improvements to the energy density of flow batteries would reduce their installed footprint, transportation costs, and installation costs and may open up new applications. This review will discuss the background, current progress, and future directions of one unique class of flow batteries that attempt to improve on the energy density of flow batteries by switching to solid electroactive materials, rather than dissolved redox compounds, to provide the electrochemical energy storage.

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