3D Carbon Networks: Design and Applications in Sodium Ion Batteries

Yuan, Guobao; Liu, Dapeng; Feng, Xun

doi:10.1002/cplu.202100272

Cited by 14 publications

(5 citation statements)

References 162 publications

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“…The different structural characteristics of electrodes lead to diverse advantages in SIBs especially with low-dimensional nanostructures (0D, 1D, 2D, and 3D) [29]. 0D, 1D, and 2D are favorable for accelerating the transport of electrons or Na + ions whereas 3D hierarchical structures integrate the advantages of both low-dimensional nanostructures and microscale materials, resulting in enhanced structural stability and inhibition of agglomeration [26].…”

Section: Smart Nanostructures For Sodium-ion Batteriesmentioning

confidence: 99%

Nanocarbon in Sodium‐ion Batteries – A Review. Part 1: Zero‐dimensional Carbon Dots

2023

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In the recent past, sodium‐ion batteries (SIBs) have assumed to be an alternative to lithium‐ion batteries (LIBs) as sodium is abundantly available in nature. It is low cost with its storage mechanism almost similar to LIBs. The ionic radius of Na is three‐fold larger than that of Li and offers a low standard electrochemical potential than Li. The built‐in SIBs are better than LIBs. However, in terms of energy density, specific capacity, and rate capability, there is a lack of suitable anode materials for SIBs. Interestingly, carbon‐based quantum dots are a new class of zero‐dimensional (0D) material with ultra‐small size having unique physicochemical properties. The utility of carbon quantum dots (CQDs), graphene quantum dots (GQDs) and graphitic carbon nitride quantum dots (g‐C3N4 QDs) has drawn attention to the scientists and industrialists for the development of SIBs due to their quantum size and structural diversities, physicochemical properties, amenability for doping with heteroatoms and good electrical conductivity. This article reviews the role of various carbon quantum dots commonly used as anodes in SIBs.

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Section: Smart Nanostructures For Sodium-ion Batteriesmentioning

confidence: 99%

Nanocarbon in Sodium‐ion Batteries – A Review. Part 1: Zero‐dimensional Carbon Dots

2023

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“…The above two batteries share great similarities, but the larger size and higher redox potential of Na + lead to unavoidable disadvantages, commonly used for graphite anode of LiBs does not intercalate sodium to any appreciable extent [5,6] . However, the shortage of lithium resources and the plentiful of sodium resources have led to the consideration of SiBs as a substitute for LiBs, so identifying a suitable anode material is required for SiBs [7–11] …”

Section: Introductionmentioning

confidence: 99%

“…[5,6] However, the shortage of lithium resources and the plentiful of sodium resources have led to the consideration of SiBs as a substitute for LiBs, so identifying a suitable anode material is required for SiBs. [7][8][9][10][11] Depending on the lithium/sodium storage mechanism, there are intercalation-type anode materials or alloying-type anode materials in addition to conversion-type anode materials. The mechanism of intercalation-type anode materials is mainly the reversible intercalation and extraction of Li + /Na + in the lattice of materials with a layered structure, but it is influenced by the crystal and cation size.…”

Section: Introductionmentioning

confidence: 99%

The Anode Materials for Lithium‐Ion and Sodium‐Ion Batteries Based on Conversion Reactions: a Review

Wang

2023

ChemElectroChem

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Due to its characteristics of not being constrained by the lattice structure and cation size, electrochemical conversion reaction is becoming an increasingly prominent type of electrochemical reaction. Lithium‐ion batteries can achieve superior performance by utilizing conversion reactions, Moreover, Sodium‐ion batteries are expected to become alternatives to lithium‐ion because of the plentiful sodium resources. This review discusses the most current developments and unmet needs in anode materials based on conversion reactions of Lithium‐ion and sodium‐ion batteries, as well as various synthesis techniques, morphological characteristics, and electrochemical properties.

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“…Nowadays, sodium‐ion batteries (SIBs) have been considered to be a very promising candidate for the next generation large‐scale electrochemical energy storage devices by virtue of the abundance of sodium resources and attractive cost‐effectiveness compared with the mature lithium‐ion batteries. [ 1 ] However, the sluggish diffusion kinetics and larger radius of sodium ions tend to cause structure collapse of electrode materials during charge/discharge. [ 2 ] Design and development on high‐performance anode materials is hence highly desirable to promote the practical application of SIBs.…”

Section: Introductionmentioning

confidence: 99%

“…The construction of “all in one” 3D hierarchical electrode can effectively solve these aforementioned issues via in situ growth of electroactive materials on flexible carbon substrates. [ 1c,8 ] This strategy could help eliminate the utilization of insulated adhesives and provide a good 3D conductive network for transport of electrons, and more importantly avoid the attenuation of electrochemical performance due to the failure of adhesive. [ 9 ] Moreover, well‐tailored hierarchical nanostructures including nanosheets, nanoneedles, nanofibers, and nanotubes would be more favorable for integral structural stability during the electrochemical process.…”

Section: Introductionmentioning

confidence: 99%

In Situ Fabrication of Porous Co_xP Hierarchical Nanostructures on Carbon Fiber Cloth with Exceptional Performance for Sodium Storage

et al. 2022

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Superior high‐rate performance and ultralong cycling life have been constantly pursued for rechargeable sodium‐ion batteries (SIBs). In this work, a facile strategy is employed to successfully synthesize porous CoxP hierarchical nanostructures supported on a flexible carbon fiber cloth (CoxP@CFC), constructing a robust architecture of ordered nanoarrays. Via such a unique design, porous and bare structures can thoroughly expose the electroactive surfaces to the electrolyte, which is favorable for ultrafast sodium‐ion storage. In addition, the CFC provides an interconnected 3D conductive network to ensure firm electrical connection of the electrode materials. Besides the inherent flexibility of the CFC, the integration of the hierarchical structures of CoxP with the CFC, as well as the strong synergistic effect between them, effectively help to buffer the mechanical stress caused by repeated sodiation/desodiation, thereby guaranteeing the structural integrity of the overall electrode. Consequently, CoxP@CFC as an anode shows a record‐high capacity of 279 mAh g−1 at 5.0 A g−1 with almost no capacity attenuation after 9000 cycles.

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3D Carbon Networks: Design and Applications in Sodium Ion Batteries

Cited by 14 publications

References 162 publications

Nanocarbon in Sodium‐ion Batteries – A Review. Part 1: Zero‐dimensional Carbon Dots

Nanocarbon in Sodium‐ion Batteries – A Review. Part 1: Zero‐dimensional Carbon Dots

The Anode Materials for Lithium‐Ion and Sodium‐Ion Batteries Based on Conversion Reactions: a Review

In Situ Fabrication of Porous Co_xP Hierarchical Nanostructures on Carbon Fiber Cloth with Exceptional Performance for Sodium Storage

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3D Carbon Networks: Design and Applications in Sodium Ion Batteries

Cited by 14 publications

References 162 publications

Nanocarbon in Sodium‐ion Batteries – A Review. Part 1: Zero‐dimensional Carbon Dots

Nanocarbon in Sodium‐ion Batteries – A Review. Part 1: Zero‐dimensional Carbon Dots

The Anode Materials for Lithium‐Ion and Sodium‐Ion Batteries Based on Conversion Reactions: a Review

In Situ Fabrication of Porous CoxP Hierarchical Nanostructures on Carbon Fiber Cloth with Exceptional Performance for Sodium Storage

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In Situ Fabrication of Porous Co_xP Hierarchical Nanostructures on Carbon Fiber Cloth with Exceptional Performance for Sodium Storage