Effect of Microstructure on the Ionic Conductivity of an All Solid-State Battery Electrode

Froboese, Linus; Sichel, Jan Felix van der; Loellhoeffel, Thomas; Helmers, Laura; Kwade, Arno

doi:10.1149/2.0601902jes

Cited by 68 publications

(79 citation statements)

References 52 publications

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“…The method is able to reproduce the increment and further consolidation of the electrical conductivity in dependence on the CB content, enabling its use for further investigations on electrode morphology and additional applications. Moreover, the tortuosity of the simulated electrodes is numerically calculated and the ionic conductivity is derived according to . In fact, bearing in mind the gained outcomes, it is not advisable to increase the amount of CB above 5 wt %, due to the almost discernible increase in electrical conductivity and consequent hindering of ionic diffusion.…”

Section: Resultsmentioning

confidence: 99%

“…Finally, a calendering step was carried out via a laboratory calender device (Saueressig GmbH) with a roll temperature of 90 °C and a roll speed of 0.1 m min −1 to reach the targeted electrode thickness of 60 mm. The electrode mass was determined with a laboratory scale and the thickness with an indicating gauge (Mitutoyo, Planolith, ID‐C112AXB); both are required to calculate the porosity of the electrodes according to Froboese et al . The electrical conductivity measurements were performed via a two‐point approach with a material testing machine (Z020; Zwick GmbH & Co. KG).…”

Section: Materials and Experimental Methodsmentioning

confidence: 99%

“…Taking this into consideration, the porosity was substituted in Eq. by the volume fraction of the electrolyte, an approach that has already been successfully taken in . The electrolyte diffusion coefficient equals 2 × 10 −4 S cm −1 , as reported by Pesko et al .…”

Section: Computational Modelingmentioning

confidence: 99%

“…Nevertheless, little research has been conducted on these properties within the context of ASSB, so far. One of the few works has dealt with the ionic conductivity of the solid electrolyte, demonstrating the influence of various ASSB electrode structures on this parameter . Hou et al confirmed the major significance of interconnected electronic pathways in the electrochemical performance of a lithium‐sulfur ASSB and experimentally verified the equal relevance of electron conduction in comparison to ion transfer.…”

Section: Introductionmentioning

confidence: 99%

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Modeling the Electrical Conductive Paths within All‐Solid‐State Battery Electrodes

et al. 2020

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All-solid-state batteries constitute a very promising energy storage device. Two very important properties of these battery cells are the ionic and the electrical conductivity, which describe the ion and the electron transport through the electrodes, respectively. In this work, a numerical method is presented to model the electrical conductivity, considering the outcome of discrete-element method simulations and the intrinsic conductivities of both the active material particles and the conductive additive particles. The results are calibrated and validated with the help of experimental data of real manufactured electrodes. The tortuosity, which strongly influences the ionic conductivity, is also presented for the analyzed electrodes, taking their microstructure into account.

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Section: Resultsmentioning

confidence: 99%

Section: Materials and Experimental Methodsmentioning

confidence: 99%

Section: Computational Modelingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Modeling the Electrical Conductive Paths within All‐Solid‐State Battery Electrodes

et al. 2020

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“…Although many efforts have been made to overcome the chemo-mechanical challenges, the issues caused by the SSE matrix complex and electrode manufacture remain uncovered, which inhibits the large-scale application of SSBs (Kato et al, 2018). Apart from the critical electrode-electrolyte interface, the inevitable voids in the SSE matrix not only reduce the lithium diffusion paths in the SSE but also provide space for lithium dendrite integration (Froboese et al, 2019). Therefore, developing dense electrolyte and electrode with fewer spaces has become another critical approach.…”

Section: Manufacturing Solid-state Batteriesmentioning

confidence: 99%

Fundamentals of Electrolytes for Solid-State Batteries: Challenges and Perspectives

Wang

et al. 2020

Front. Mater.

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Compared with traditional lithium-ion systems, solid-state batteries could achieve high safety and energy density. Although great improvements have been made, especially in solid-state electrolytes, fundamental challenges still remain for the solid-state systems in terms of chemistry and mechanics. This review summarizes the fundamental issues in solid-state batteries with a focus on three critical phenomena: (i) the principles of developing high ionic conductors, (ii) structural evolution at chemically unstable electrolyte-electrode interfaces, and (iii) the effects of manufacturing solid-state batteries, including electrode, and electrolyte design. The future perspectives are also outlined to guide the development of solid-state batteries.

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Linking Solid Electrolyte Degradation to Charge Carrier Transport in the Thiophosphate‐Based Composite Cathode toward Solid‐State Lithium‐Sulfur Batteries

Ohno

Rosenbach

Dewald

et al. 2021

Adv Funct Materials

164

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Solid‐state lithium‐sulfur batteries (SSLSBs) have the potential to cause a paradigm shift in energy storage. The use of emerging highly‐conductive solid electrolytes enables high energy and power densities. However, the need for an intimate mixture of electrolyte and conductive additives to compensate for the insulating nature of cathode active materials S8 and Li2S induces intense electrolyte degradation. Thus, it is paramount to understand better the electrochemical and transport properties of the cathode composite with extremely high interface density among cathode components. Here, by utilizing a ball‐milled composite of the lithium argyrodite Li6PS5Cl and carbon as a model electrode, the stability, reversibility, and transport in the composite as functions of cathode loading, the volume fraction of conducting phase, temperature, and applied potentials are comprehensively investigated. Comparing the onset potentials of electrolyte degradation and the sharp drop in the effective ionic conductivity of the composite determined through transmission‐line model analysis, successful enhancement of the capacity retention of SSLSBs is demonstrated by balancing between the attainable capacity and effective carrier transport, achieving a high areal capacity of 3.68 mAh cm−2 after 100 cycles at room temperature. The here‐observed analysis is applicable to any solid‐state composite with electrically insulating active materials.

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Effect of Microstructure on the Ionic Conductivity of an All Solid-State Battery Electrode

Cited by 68 publications

References 52 publications

Modeling the Electrical Conductive Paths within All‐Solid‐State Battery Electrodes

Modeling the Electrical Conductive Paths within All‐Solid‐State Battery Electrodes

Fundamentals of Electrolytes for Solid-State Batteries: Challenges and Perspectives

Linking Solid Electrolyte Degradation to Charge Carrier Transport in the Thiophosphate‐Based Composite Cathode toward Solid‐State Lithium‐Sulfur Batteries

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