Waterborne polyurethane as a carbon coating for micrometre-sized silicon-based lithium-ion battery anode material

Yan, Chunfeng; Huang, Tao; Zheng, Xinwei; Gong, Cui-Ran; Wu, Maoxiang

doi:10.1098/rsos.180311

Cited by 4 publications

(1 citation statement)

References 38 publications

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“…[ 205 ] The physical barrier of the carbon shell isolates the contact between silicon and electrolyte, thereby improving the stability of the SEI film. [ 206 ] To address the issue of significant volume changes in silicon electrodes during cycling, Zhi and colleagues proposed a new design for skin‐like covalent encapsulation of silicon electrodes. This methodology is described as 2D covalent encapsulation using chemical vapor deposition (CVD), as illustrated in Figure a.…”

Section: Solving Anode Challenges By Core–shell Strategiesmentioning

confidence: 99%

Review of the Scalable Core–Shell Synthesis Methods: The Improvements of Li‐Ion Battery Electrochemistry and Cycling Stability

2023

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The demand for lithium‐ion batteries has significantly increased due to the increasing adoption of electric vehicles (EVs). However, these batteries have a limited lifespan, which needs to be improved for the long‐term use needs of EVs expected to be in service for 20 years or more. In addition, the capacity of lithium‐ion batteries is often insufficient for long‐range travel, posing challenges for EV drivers. One approach that has gained attention is using core–shell structured cathode and anode materials. That approach can provide several benefits, such as extending the battery lifespan and improving capacity performance. This paper reviews various challenges and solutions by the core–shell strategy adopted for both cathodes and anodes. The highlight is scalable synthesis techniques, including solid phase reactions like the mechanofusion process, ball‐milling, and spray‐drying process, which are essential for pilot plant production. Due to continuous operation with a high production rate, compatibility with inexpensive precursors, energy and cost savings, and an environmentally friendly approach that can be carried out at atmospheric pressure and ambient temperatures. Future developments in this field may focus on optimizing core–shell materials and synthesis techniques for improved Li‐ion battery performance and stability.

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Section: Solving Anode Challenges By Core–shell Strategiesmentioning

confidence: 99%

Review of the Scalable Core–Shell Synthesis Methods: The Improvements of Li‐Ion Battery Electrochemistry and Cycling Stability

2023

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Advances and Future Prospects of Micro‐Silicon Anodes for High‐Energy‐Density Lithium‐Ion Batteries: A Comprehensive Review

Sun,

Liu,

Wang

et al. 2024

Adv Funct Materials

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Silicon (Si), stands out for its abundant resources, eco‐friendliness, affordability, high capacity, and low operating potential, making it a prime candidate for high‐energy‐density lithium‐ion batteries (LIBs). Notably, the breakthrough use of nanostructured Si (nSi) has paved the way for the commercialization of Si anodes. Despite this, challenges like high processing costs, severe side reactions, and low volumetric energy density have impeded widespread industrial adoption. Micron‐scale Si (µSi) has always faced setbacks compared to nSi due to its greater volume expansion. However, recent years have witnessed a resurgence of interest in µSi‐based anodes. Capitalizing on its inherent advantages, including low cost and high tap density, µSi has once again captured the attention of both academic and industrial communities. This review begins by contrasting the strengths and weaknesses of µSi and nSi, then outline potential solutions to enhance µSi performance, covering aspects like structural regulation, composite anodes, binder design, and electrolyte exploration. Additionally, this work explores the application of machine learning‐assisted high‐throughput screening. Concluding the review, this work provides insights into the future prospects of µSi in LIBs, outlining challenges and proposing integrated coping strategies. This review anticipates that it will provide valuable perspectives for the commercial application of high‐energy‐density Si‐based anodes.

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Waterborne polyurethane-based electrode nanomaterials

Majeed

Rasheed

Shafi

et al. 2021

Biopolymeric Nanomaterials

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Waterborne polyurethane as a carbon coating for micrometre-sized silicon-based lithium-ion battery anode material

Cited by 4 publications

References 38 publications

Review of the Scalable Core–Shell Synthesis Methods: The Improvements of Li‐Ion Battery Electrochemistry and Cycling Stability

Review of the Scalable Core–Shell Synthesis Methods: The Improvements of Li‐Ion Battery Electrochemistry and Cycling Stability

Advances and Future Prospects of Micro‐Silicon Anodes for High‐Energy‐Density Lithium‐Ion Batteries: A Comprehensive Review

Waterborne polyurethane-based electrode nanomaterials

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