Polymeric Binder Design for Sustainable Lithium-ion Battery
By A Mystery Man Writer
Description
The design of binders plays a pivotal role in achieving enduring high power in lithium-ion batteries (LIBs) and extending their overall lifespan. This review underscores the indispensable characteristics that a binder must possess when utilized in LIBs, considering factors such as electrochemical, thermal, and dispersion stability, compatibility with electrolytes, solubility in solvents, mechanical properties, and conductivity. In the case of anode materials, binders with robust mechanical properties and elasticity are imperative to uphold electrode integrity, par-ticularly in materials experiencing substantial volume changes. For cathode materials, the se-lection of a binder hinges on the crystal structure of the cathode material. Other vital consid-erations in binder design encompass cost-effectiveness, adhesion, processability, and envi-ronmental friendliness. Incorporating low-cost, eco-friendly, and biodegradable polymers can contribute significantly to sustainable battery development. This review serves as an invaluable resource for comprehending the prerequisites of binder design in high-performance LIBs and offers insights into binder selection for diverse electrode materials. The findings and principles articulated in this review can be extrapolated to other advanced battery systems, charting a course for the development of next-generation batteries characterized by enhanced perfor-mance and sustainability.
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Polymers Special Issue : Advances in Polymer Applied in
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Recent Developments and Challenges in Hybrid Solid Electrolytes
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Figure 4 from Effect of Binder Architecture on the Performance of
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Progress of 3D network binders in silicon anodes for lithium ion
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Table 1 from Effect of Binder Architecture on the Performance of
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Incorporation of aniline tetramer into alginate-grafted
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Application of PFM-based conducting polymer binders with different
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