Recent advances of electrode materials for low-cost sodium-ion batteries towards practical application for grid energy storage

Li, Yunming; Lu, Yaxiang; Zhao, Chenglong; Hu, Yong‐Sheng; Titirici, Maria‐Magdalena; Li, Hong; Huang, Xuejie; Chen, Liquan

doi:10.1016/j.ensm.2017.01.002

Cited by 480 publications

(297 citation statements)

References 191 publications

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“…[29,30] During the long period of academic research on SIBs, there have been a number of achievements, especially on the active materials and electrolyte. Meanwhile, many review papers have also been published to describe different types of active materials and to analyze proposed reaction mechanisms, [31][32][33][34][35][36][37][38] which will not be discussed in this report in detail. From the perspective of future practical applications and commercialization, however, much more consideration should be paid to the sodium ion full-cell system rather than the halfcell system.…”

mentioning

confidence: 99%

Sodium‐Ion Batteries: From Academic Research to Practical Commercialization

Deng

Luo

Chou

et al. 2017

Advanced Energy Materials

523

347

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Sodium‐ion batteries (SIBs) have been considered as the most promising candidate for large‐scale energy storage system owing to the economic efficiency resulting from abundant sodium resources, superior safety, and similar chemical properties to the commercial lithium‐ion battery. Despite the long period of academic research, how to realize sodium‐ion battery commercialization for market applications is still a great challenge. Thus, from the perspective of future practical application, this review will identify the factors that are restricting commercialization, and evaluate the existing active materials and sodium‐ion‐based full‐cell system. The design and development trends that are needed for SIBs to meet the requirements of practical applications in large‐scale energy storage will also be discussed in detail.

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mentioning

confidence: 99%

Sodium‐Ion Batteries: From Academic Research to Practical Commercialization

Deng

Luo

Chou

et al. 2017

Advanced Energy Materials

523

347

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“…However, early work on carbonaceous materials showed undesired properties with low capacities and/or poor cyclability . Promising progress has been made in recent years through materials modifications …”

Section: Anodesmentioning

confidence: 87%

Understanding Fundamentals and Reaction Mechanisms of Electrode Materials for Na‐Ion Batteries

Wang

Liao

et al. 2018

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Development of efficient, affordable, and sustainable energy storage technologies has become an area of interest due to the worsening environmental issues and rising technological dependence on Li-ion batteries. Na-ion batteries (NIBs) have been receiving intensive research efforts during the last few years. Owing to their potentially low cost and relatively high energy density, NIBs are promising energy storage devices, especially for stationary applications. A fundamental understanding of electrode properties during electrochemical reactions is important for the development of low cost, high-energy density, and long shelf life NIBs. This Review aims to summarize and discuss reaction mechanisms of the major types of NIB electrode materials reported. By appreciating how the material works and the fundamental flaws it possesses, it is hoped that this Review will assist readers in coming up with innovative solutions for designing better materials for NIBs.

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“…12,19,27 Carbonaceous materials are considered as the most representative anode materials owing to their abundance and high electrochemical performance, particularly hard carbon materials, which have exhibited capacities over~350 mAh g −1 . 12,19,27 Carbonaceous materials are considered as the most representative anode materials owing to their abundance and high electrochemical performance, particularly hard carbon materials, which have exhibited capacities over~350 mAh g −1 .…”

Section: Flexible Anodesmentioning

confidence: 99%

“…During the past decade, various electrode materials have been discovered and investigated for use in Na batteries, as shown in Figure 1B,C, including cathode materials [12][13][14][15] : layered oxides, 16 polyanionic compounds, 17 Prussian blue analogues, 18 sulfur and gas (O 2 and CO 2 ) etc, anodes, 14,19 carbon-based materials, 20,21 titanium-based materials, 22,23 alloy materials, 24 chalcogen-based materials, 19,25,26 organic materials, 19,25,26 Na metal anodes, 27 and so forth. During the past decade, various electrode materials have been discovered and investigated for use in Na batteries, as shown in Figure 1B,C, including cathode materials [12][13][14][15] : layered oxides, 16 polyanionic compounds, 17 Prussian blue analogues, 18 sulfur and gas (O 2 and CO 2 ) etc, anodes, 14,19 carbon-based materials, 20,21 titanium-based materials, 22,23 alloy materials, 24 chalcogen-based materials, 19,25,26 organic materials, 19,25,26 Na metal anodes, 27<...>…”

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confidence: 99%

Flexible Na batteries

Zhao

Chen

et al. 2019

InfoMat

Self Cite

112

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Flexible energy storage devices have gained significant attention because of the increasing needs of bendable displays, wearable electronics, and flexible displays. Flexible Na‐based rechargeable batteries are the promising power sources in such products due to their low cost and wide availability. In this review, we firstly introduce the structural superiority of flexible Na‐based batteries and summarize their main components including cathodes, electrolytes, and anodes. Moreover, fabrication of their flexible components is discussed in detail, with specific emphasis on material selection, particularly for solid‐state electrolytes. This is followed by an overview highlighting recent progress in the development of prototypes of flexible Na‐ion batteries and beyond. Finally, perspectives on future challenges for the development of flexible Na batteries are proposed.

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Recent advances of electrode materials for low-cost sodium-ion batteries towards practical application for grid energy storage

Cited by 480 publications

References 191 publications

Sodium‐Ion Batteries: From Academic Research to Practical Commercialization

Sodium‐Ion Batteries: From Academic Research to Practical Commercialization

Understanding Fundamentals and Reaction Mechanisms of Electrode Materials for Na‐Ion Batteries

Flexible Na batteries

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