Impact of the Carbon Matrix Composition on the S/C Cathode Porosity and Performance in Prototype Li–S Cells

Schmidt, Franz; Fiedler, Magdalena; Arlt, Tobias; De, Ankita; Hoffmann, Florian; Wilde, Fabian; Dörfler, Susanne; Schumm, Benjamin; Abendroth, Thomas; Althues, Holger; Kaskel, Stefan

doi:10.1002/ente.202300518

Energy Tech

2023

DOI: 10.1002/ente.202300518

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Impact of the Carbon Matrix Composition on the S/C Cathode Porosity and Performance in Prototype Li–S Cells

Franz Schmidt

Magdalena Fiedler

Tobias Arlt

et al.

Abstract: The lithium–sulfur battery is a promising electrochemical storage solution, especially for aviation and aeronautical applications, due to its high‐gravimetric energy density (specific energy) and the abundance of sulfur. In recent years, the number of reported prototype cells and their realized energy have increased. This underlines the progress of technology readiness of the lithium–sulfur system. However, the influence of the cathode porosity as well as the porosity of the carbon material on the performance … Show more

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2024

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Lithium‐Sulfur‐Batteries under Lean Electrolyte Conditions: Improving Rate Capability by the Choice of the Lithium Salt in Dimethoxyethane‐Hydrofluoroether‐Based Electrolyte

Kirchhoff,

Härtel,

Dörfler

et al. 2024

Batteries & Supercaps

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Lithium‐sulfur batteries (LSBs) are discussed as the most promising post‐lithium‐ion battery technology due to the high theoretical energy density and the cost‐efficient, environmental‐friendly active material sulfur. Unfortunately, LSBs still suffer from several limitations such as cycle life and rate capability. To overcome these issues, the development of adapted electrolytes is one promising path. Consequently, in this study, we focus on the influence of the lithium salt on the performance of LSBs. In a fixed solvent system without employing LiNO3, five different lithium salts are compared. The electrolyte properties as well as the influence of polysulfides are determined and discussed in relation with the battery performance. Interestingly, although the different salts lead to different electrolyte properties, only a minor influence of the salt is observed at low C‐rates. By performing a rate capability test, however, a strong influence of the lithium salt is detected at high C‐rates, with LiFSI outperforming the other salts. This correlates well with ionic conductivity and a suppressed influence of polysulfides in case of LiFSI. To verify the results, multi‐layered pouch cells were tested under lean electrolyte conditions. The study emphasizes the significance of the lithium salt and provides guidance for electrolyte design under lean electrolyte conditions.

show abstract

Lithium‐Sulfur‐Batteries under Lean Electrolyte Conditions: Improving Rate Capability by the Choice of the Lithium Salt in Dimethoxyethane‐Hydrofluoroether‐Based Electrolyte

Kirchhoff,

Härtel,

Dörfler

et al. 2024

Batteries & Supercaps

View full text Add to dashboard Cite

show abstract

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Impact of the Carbon Matrix Composition on the S/C Cathode Porosity and Performance in Prototype Li–S Cells

Cited by 1 publication

References 76 publications

Lithium‐Sulfur‐Batteries under Lean Electrolyte Conditions: Improving Rate Capability by the Choice of the Lithium Salt in Dimethoxyethane‐Hydrofluoroether‐Based Electrolyte

Lithium‐Sulfur‐Batteries under Lean Electrolyte Conditions: Improving Rate Capability by the Choice of the Lithium Salt in Dimethoxyethane‐Hydrofluoroether‐Based Electrolyte

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