Characterizing electrode materials and interfaces in solid-state batteries

In situ characterizations of solid–solid interfaces in

The solid–solid electrode–electrolyte interface represents an important component in solid-state batteries (SSBs), as ionic diffusion, reaction, transformation, and restructuring could all take place. As these processes

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About Characterizing electrode materials and interfaces in solid-state batteries

This review provides a comprehensive overview of the characterization methods and strategies applied to SSBs, and it presents the mechanistic understanding of SSB materials and interfaces that has been derived from these methods.

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This issue of MRS Bulletin focuses on the current state of the art of solid-state batteries with the most important topics related to the interface issues, advanced characterizations, and electrode chemistries, aiming to provide a comprehensive perspective for the interface and characterization.

Solid-state lithium batteries (SSLBs) have emerged as a promising alternative to conventional lithium-ion systems due to their superior safety profile, higher energy density, and potential compatibility with lithium metal anodes. However, a major challenge hindering their widespread deployment is.

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6 FAQs about [Characterizing electrode materials and interfaces in solid-state batteries]

What is a solid–solid electrode–electrolyte interface?

Marcos Lucero and Shen Qiu contributed equally to this study. The solid–solid electrode–electrolyte interface represents an important component in solid-state batteries (SSBs), as ionic diffusion, reaction, transformation, and restructuring could all take place.

How important is electrode characterization in SSB development?

Overall, the characterization of electrode materials and their interfaces has been a critical aspect of SSB development over the past decade.

Are SSB electrodes and interfaces based on image-based characterization?

Considering image-based characterization of SSBs, there have been numerous important in situand operandostudies that have revealed electrode and interface behavior at the microscale, including X-ray imaging and optical microscopy.

What is a non-ideal contact at the electrode/solid electrolyte interface?

(American Chemical Society) A non-ideal contact at the electrode/solid electrolyte interface of a solid-state battery arising due to pores (voids) or inclusions results in a geometric constriction effect that severely deteriorates the elec. transport properties of the battery cell.

What is a composite electrode in a lithium battery?

(Elsevier B.V.) Electrodes in high-energy all-solid-state lithium batteries are typically composites, consisting of mixts. of a Li storage material and a solid electrolyte. Ion transport in such composite electrodes plays an important role for battery performance.

Why should we study electrode–electrode interfaces in SSBs?

Therefore, study of the electrode–electrode interfaces in SSBs, particularly during battery operation, is critical to understanding the formation, reaction, and transformation of any interphase, thus providing insights for tuning of each component and improving the performance of SSBs.