A Full Oxide-Based Solid-State Lithium Battery and Its Unexpected Cathode Degradation Mechanism

Han, Sangwook; Kil, Donghyun; Lee, Sunyoung; Park, Hyeokjun; Ko, Kun-hee; Kim, Wonju; Park, Jooha; Lim, Chanhyuk; Yoon, Kyungho; Noh, Joohyeon; Eum, Donggun; Won, Daero; Kang, Kisuk

doi:10.1021/acsenergylett.3c01759

Cited by 2 publications

References 85 publications

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Understanding and unveiling the electro‐chemo‐mechanical behavior in solid‐state batteries

Zhong,

Zhang,

Zhang

et al. 2024

SusMat

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Solid‐state batteries (SSBs) are attracting growing interest as long‐lasting, thermally resilient, and high‐safe energy storage systems. As an emerging area of battery chemistry, there are many issues with SSBs, including strongly reductive lithium anodes, oxidized cathodes (state of charge), the thermodynamic stability limits of solid‐state electrolytes (SSEs), and the ubiquitous and critical interfaces. In this Review, we provided an overview of the main obstacles in the development of SSBs, such as the lithium anode|SSEs interface, the cathode|SSEs interface, lithium‐ion transport in the SSEs, and the root origin of lithium intrusions, as well as the safety issues caused by the dendrites. Understanding and overcoming these obstacles are crucial but also extremely challenging as the localized and buried nature of the intimate contact between electrode and SSEs makes direct detection difficult. We reviewed advanced characterization techniques and discussed the complex ion/electron‐transport mechanism that have been plaguing electrochemists. Finally, we focused on studying and revealing the coupled electro‐chemo‐mechanical behavior occurring in the lithium anode, cathode, SSEs, and beyond.

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Understanding and unveiling the electro‐chemo‐mechanical behavior in solid‐state batteries

Zhong,

Zhang,

Zhang

et al. 2024

SusMat

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Disorder-driven Sintering-free Garnet-type Solid Electrolytes

Kwon,

Gwon,

Bae

et al. 2024

Preprint

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Oxide ceramic electrolytes for realization of high-energy lithium metal batteries generally require a series of high-temperature processes for the formation of the desired phase and inter-particle sintering. The high-temperature processing can lead to compositional changes or mechanical deformation, consequently, resulting in serious issues with material reliabilities. Here, we introduce a disorder-driven sintering-free garnet-type solid electrolyte using a novel approach for creating an amorphous matrix followed by a single-step mild heat-treatment. The softened mechanical property (yield pressure, Py = 359.8 MPa) of disordered base materials can achieve a facile formation of a dense amorphous matrix and contributes to maintaining inter-particle connectivity during crystallization. Remarkably, the formation of the highly conductive cubic-phase garnet is triggered at a drastically lowered temperature of 350°C, leading to high ionic conductivity (σLi+ = 1.8 × 10–4 S/cm at 25°C) through a single-step mild heat treatment at 500°C. The disorder-driven garnet solid electrolyte exhibits electrochemical performance similar to that of the conventional garnet solid electrolyte sintered at > 1100°C. This electrolyte exhibits the lowest processing temperature ever reported for garnet-type solid electrolytes with a high lithium ionic conductivity of ~ 10–4 S/cm. These findings will promote the fabrication of uniform, thin, and wide solid electrolyte membranes, which is a significant hurdle in the commercialization of oxide-based lithium metal batteries, and demonstrate the untapped capabilities of garnet-type oxide solid electrolytes.

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A Full Oxide-Based Solid-State Lithium Battery and Its Unexpected Cathode Degradation Mechanism

Cited by 2 publications

References 85 publications

Understanding and unveiling the electro‐chemo‐mechanical behavior in solid‐state batteries

Understanding and unveiling the electro‐chemo‐mechanical behavior in solid‐state batteries

Disorder-driven Sintering-free Garnet-type Solid Electrolytes

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