2021
DOI: 10.1002/adma.202005305
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Stamping Flexible Li Alloy Anodes

Abstract: Li metal holds great promise to be the ultimate anode choice owing to its high specific capacity and low redox potential. However, processing Li metal into thin‐film anode with high electrochemical performance and good safety to match commercial cathodes remains challenging. Herein, a new method is reported to prepare ultrathin, flexible, and high‐performance Li–Sn alloy anodes with various shapes on a number of substrates by directly stamping a molten metal solution. The printed anode is as thin as 15 µm, cor… Show more

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Cited by 76 publications
(59 citation statements)
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“…Owing to the good electrical conductivity and mechanical properties, Li-based alloys generally ensure rapid Li + diffusion and inhibit lithium dendrite growth by reducing the Li nucleation barrier. 61,62 Huggins et al previously emphasised the importance of an interface with high ionic diffusion for the suppression of dendrites. 63 For instance, Au, Ag, Zn, and Mg can be lithiated to form solid solution species that exhibit zero overpotential during lithium deposition, while C, Sn, and Si species have low solubility in lithium to form composite alloy phases that exhibit lower nucleation overpotentials.…”
Section: In Situ Generated Interfacial Layer Prepared Via Lrrsmentioning
confidence: 99%
“…Owing to the good electrical conductivity and mechanical properties, Li-based alloys generally ensure rapid Li + diffusion and inhibit lithium dendrite growth by reducing the Li nucleation barrier. 61,62 Huggins et al previously emphasised the importance of an interface with high ionic diffusion for the suppression of dendrites. 63 For instance, Au, Ag, Zn, and Mg can be lithiated to form solid solution species that exhibit zero overpotential during lithium deposition, while C, Sn, and Si species have low solubility in lithium to form composite alloy phases that exhibit lower nucleation overpotentials.…”
Section: In Situ Generated Interfacial Layer Prepared Via Lrrsmentioning
confidence: 99%
“…Therefore, it is regarded Li-rich composite alloys have attracted great attention as a novel electrode because they can present a matrix to promote the uniform plating/stripping behaviors of Li. [167][168][169][170] The diffusion of Li atoms in alloys involves another diffusion mechanism. Li atoms are much smaller than the matrix atoms and distributed in the lattice gaps of the matrix.…”
Section: Diffusion Mechanismmentioning
confidence: 99%
“…Due to its simple operation, cost-effectiveness, high reliability, and high efficiency, transfer printing can fabricate tiny, ultrathin, and exible batteries in high-throughput manner. 44 However, the adhesion requirement at the interfaces is hard to satisfy and the stamps should be designed according to the desirable printed patterns.…”
Section: Major Printing Techniques For Solidstate Batteriesmentioning
confidence: 99%
“…Besides, this method can be readily extended to other alloy anodes as well as to versatile substrates with any shapes, which promotes the practical usage of dendrite-free Li anode in thin-lm batteries. 44 Printing an Li protective layer with good mechanical strength and stable chemical properties is also a promising method for suppressing Li dendrite growth and large volume expansion. Various printing techniques can ensure controllable thickness, a low-cost process, scalable methodology, and reliable performance.…”
Section: Printing Strategies For Anodesmentioning
confidence: 99%