Insights into Enhancing Electrochemical Performance of Li-Ion Battery Anodes via Polymer Coating

Abdollahifar, Mozaffar; Molaiyan, Palanivel; Perovic, Milena; Kwade, Arno

doi:10.3390/en15238791

Cited by 12 publications

(12 citation statements)

References 198 publications

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“…However, there are many challenges associated with battery anode materials, such as low specific capacity, volume change, during lithiation and delithiation, and unwanted side reactions. [11][12][13] To overcome these challenges, researchers have been developing various strategies to improve the performance and stability of anode materials, i.e. surface modification by coating, nanostructuring, and composite formation.…”

Section: Anode Challenges From the Sustainability Viewpointmentioning

confidence: 99%

Towards greener batteries: sustainable components and materials for next-generation batteries

Molaiyan,

Bhattacharyya,

dos Reis

et al. 2024

Green Chem.

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Section: Anode Challenges From the Sustainability Viewpointmentioning

confidence: 99%

Towards greener batteries: sustainable components and materials for next-generation batteries

Molaiyan,

Bhattacharyya,

dos Reis

et al. 2024

Green Chem.

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“…Si anodes, with ten times the theoretical capacity of graphite anodes, have attracted considerable research attention for next‐generation LIBs comparing the specific capacity of 4212 mAh g −1 for Li 4.4 Si to Gr anode with only 372 mAh g −1 . [ 103 ] Besides, Si is the second‐most abundant element in the earth's crust, and it is environmentally benign and has low electrochemical potential. However, Si has a huge volume change during (de)lithiation, a common drawback in Si‐alloy anodes, leading to severe particle pulverization and the formation of unstable solid‐electrolyte interphase, leading to increasing internal resistance and rapid capacity decay.…”

Section: Performance Of Calendered Lib Electrodesmentioning

confidence: 99%

Insights into Influencing Electrode Calendering on the Battery Performance

Abdollahifar

Cavers

Scheffler

et al. 2023

Advanced Energy Materials

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As the demand for lithium‐ion batteries (LIBs) continuously grows, the necessity to improve their efficiency/performance also grows. For this reason, optimization of the individual production steps is critical. Calendering is a crucial production step whereby electrode coatings are compacted to targeted densities. This process affects the porosity, adhesion, thickness, wettability, and charge transport properties of the electrodes, as well as the homogeneity of the coatings. Optimal calendered electrodes improve volumetric energy density, cyclic stability, and rate capability of the cells and also enhance the structural stability of the active material, which affects electrode safety and polarization. This article outlines the fundamental processes and mechanisms, as well as how modeling, simulation, and tomography can be used to optimize these processes. Additionally, the influence of calendering on a wide range of anode and cathode active materials is discussed. This review serves to give a deeper understanding into the calendering process‐structure‐performance relationships, and how they can be optimized to improve the performance of LIBs.

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“…[ 168 ] Surface coatings are typically metal rich mineral phases; oxides, fluorides and phosphates are common [ 7 ] as well as polymer coatings. [ 169 ] Surface coatings should be multifunctional in their benefits. [ 170 ] Different minerals used as surface coatings provide variable benefits; a review into surface coatings within electrodes undergoing sodium intercalation stated phosphates as beneficial for ionic diffusion, carbon coatings for electronic conductivity and metal oxides for structural stability.…”

Section: Crystallographic Enhancement Techniquesmentioning

confidence: 99%

Crystallography of Active Particles Defining Battery Electrochemistry

Morley,

George,

Hadler

et al. 2023

Advanced Energy Materials

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Crystallographic features of battery active particles impose an inherent limitation on their electrochemical figures of merit namely capacity, roundtrip efficiency, longevity, safety, and recyclability. Therefore, crystallographic properties of these particles are increasingly measured not only to clarify the principal pathways by which they store and release charge but to realize the full potential of batteries. Here, state‐of‐the‐art advances in Li+, K+, and Na+ chemistries are reviewed to reiterate the links between crystallography variations and battery electrochemical trends. These manifest at different length scales and are accompanied by a multiplicity of processes such as doping, cation disorder, directional crystal growth and extra redox. In light of this, an emphasis is placed on the need for more accurate correlations between crystallographic structure and battery electrochemistry in order to harness crystallographic beneficiation into electrode material design and manufacture, translating into high‐performance and safe energy storage solutions.

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Insights into Enhancing Electrochemical Performance of Li-Ion Battery Anodes via Polymer Coating

Cited by 12 publications

References 198 publications

Towards greener batteries: sustainable components and materials for next-generation batteries

Towards greener batteries: sustainable components and materials for next-generation batteries

Insights into Influencing Electrode Calendering on the Battery Performance

Crystallography of Active Particles Defining Battery Electrochemistry

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