Ion Mobility in Crystalline Battery Materials

Sotoudeh, Mohsen; Baumgart, Sebastian; Dillenz, Manuel; Döhn, Johannes; Forster‐Tonigold, Katrin; Helmbrecht, Katharina; Stottmeister, Daniel; Groß, Axel

doi:10.1002/aenm.202302550

“…The lattices of cellulose-derived carbon materials change with different synthesis methods that affects the migrating ions. The understanding and optimizing ion mobility for the development of advanced and efficient battery materials is very important [ 151 ]. A shortened ion diffusion path facilitates the enhanced mobility of ions within both the electrode and electrolyte, thereby resulting in an elevated ion diffusion coefficient.…”

Section: Limitations Of Cellulose-derived Carbon Materials At Rate Pe...mentioning

confidence: 99%

Recent Progress in Improving Rate Performance of Cellulose-Derived Carbon Materials for Sodium-Ion Batteries

Wang,

Zhang,

Zhang

et al. 2024

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Cellulose-derived carbon is regarded as one of the most promising candidates for high-performance anode materials in sodium-ion batteries; however, its poor rate performance at higher current density remains a challenge to achieve high power density sodium-ion batteries. The present review comprehensively elucidates the structural characteristics of cellulose-based materials and cellulose-derived carbon materials, explores the limitations in enhancing rate performance arising from ion diffusion and electronic transfer at the level of cellulose-derived carbon materials, and proposes corresponding strategies to improve rate performance targeted at various precursors of cellulose-based materials. This review also presents an update on recent progress in cellulose-based materials and cellulose-derived carbon materials, with particular focuses on their molecular, crystalline, and aggregation structures. Furthermore, the relationship between storage sodium and rate performance the carbon materials is elucidated through theoretical calculations and characterization analyses. Finally, future perspectives regarding challenges and opportunities in the research field of cellulose-derived carbon anodes are briefly highlighted.

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Tuning Ion Mobility in Lithium Argyrodite Solid Electrolytes via Entropy Engineering

Lin,

Schaller,

Indris

et al. 2024

Angewandte Chemie

0

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The development of improved solid electrolytes (SEs) plays a crucial role in the advancement of bulk‐type solid‐state battery (SSB) technologies. Recently, multicomponent or high‐entropy SEs are gaining increased attention for their advantageous charge transport and (electro)chemical properties. However, a comprehensive understanding of how configurational entropy affects ionic conductivity is largely lacking. Herein we have investigated a series of multication‐substituted lithium argyrodites with the general formula Li6+x[M1aM2bM3cM4d]S5I, with M being P, Si, Ge, and Sb. Structure‐property relationships related to ion mobility were probed using a combination of diffraction techniques, solid‐state nuclear magnetic resonance spectroscopy, and charge‐transport measurements. We present, to the best of our knowledge, the first experimental evidence of a direct correlation between occupational disorder in the cationic host lattice and lithium transport. By controlling the configurational entropy through the composition, high bulk ionic conductivities up to 18 mS cm−1 at room temperature were achieved for optimized lithium argyrodite compositions. Our results indicate the possibility of improving ionic conductivity in ceramic ion conductors via entropy engineering, unlocking the compositional limitations for the design of advanced electrolytes and opening up new avenues in the field.

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Tuning Ion Mobility in Lithium Argyrodite Solid Electrolytes via Entropy Engineering

Lin,

Schaller,

Indris

et al. 2024

Angew Chem Int Ed

0

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The development of improved solid electrolytes (SEs) plays a crucial role in the advancement of bulk‐type solid‐state battery (SSB) technologies. Recently, multicomponent or high‐entropy SEs are gaining increased attention for their advantageous charge transport and (electro)chemical properties. However, a comprehensive understanding of how configurational entropy affects ionic conductivity is largely lacking. Herein we have investigated a series of multication‐substituted lithium argyrodites with the general formula Li6+x[M1aM2bM3cM4d]S5I, with M being P, Si, Ge, and Sb. Structure‐property relationships related to ion mobility were probed using a combination of diffraction techniques, solid‐state nuclear magnetic resonance spectroscopy, and charge‐transport measurements. We present, to the best of our knowledge, the first experimental evidence of a direct correlation between occupational disorder in the cationic host lattice and lithium transport. By controlling the configurational entropy through the composition, high bulk ionic conductivities up to 18 mS cm−1 at room temperature were achieved for optimized lithium argyrodite compositions. Our results indicate the possibility of improving ionic conductivity in ceramic ion conductors via entropy engineering, unlocking the compositional limitations for the design of advanced electrolytes and opening up new avenues in the field.

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Ion Mobility in Crystalline Battery Materials

Cited by 4 publications

References 274 publications

Recent Progress in Improving Rate Performance of Cellulose-Derived Carbon Materials for Sodium-Ion Batteries

Recent Progress in Improving Rate Performance of Cellulose-Derived Carbon Materials for Sodium-Ion Batteries

Tuning Ion Mobility in Lithium Argyrodite Solid Electrolytes via Entropy Engineering

Tuning Ion Mobility in Lithium Argyrodite Solid Electrolytes via Entropy Engineering

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