Toward the Scale‐Up of Solid‐State Lithium Metal Batteries: The Gaps between Lab‐Level Cells and Practical Large‐Format Batteries

Xu, Lei; Lu, Yang; Zhao, Chen‐Zi; Yuan, Hong; Zhu, Gaolong; Hou, Li‐Peng; Zhang, Qiang; Huang, Jia‐Qi

doi:10.1002/aenm.202002360

Cited by 121 publications

(86 citation statements)

References 308 publications

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“…[35] However, compared to LIB, the solid-state battery is still in its infancy and most practical experience exists only at the laboratory level. Xu et al [36] recently reviewed the state-of-the-art regarding scalability of LMSSB, pointing out the gaps between lab-level cells and practical large-format batteries. Wang et al [37] provided a very recent perspectives article dealing with the transition of SSB from lab to market, especially highlighting the links between electro-chemo-mechanics and practical considerations.…”

Section: Manufacturing and Costsmentioning

confidence: 99%

“…Besides critical issues regarding large scale production and costs of different types of SSE and the composite cathode, which are similar for SSB, LMSSB, and AFSSB, the scalability of anode manufacturing and cell assembly still remains challenging. [36,39] The high reactivity of Li with components of ambient air (oxygen, nitrogen, carbon dioxide, moisture) [40] requires demanding dry room conditions, which comes at high acquisition, operating and maintenance costs. Alternatively, the application of an additional protective layer is investigated to increase the oxidation stability during manufacturing, [33,41] which, however, means additional process steps and corresponding costs.…”

Section: Manufacturing and Costsmentioning

confidence: 99%

“…[17,47] However, direct transfer of these strategies to practical batteries appears not promising in most cases. [36] The strategies at the lab-level help tremendously in solving the problem from the mechanism point of view. However, rational application techniques are also important to realize these solutions in scaled-up battery systems.…”

Section: Manufacturing and Costsmentioning

confidence: 99%

“…This makes it difficult to estimate the actual achievable energy density and can result in performance parameters that are significantly behind those of conventional LIBs. [36] Randau et al provided a comprehensive analysis, benchmarking the performance of solid-state lithium batteries. [255] Based on their literature survey and extensive analysis, the authors concluded that the differences in specific energy and specific power of available solid state batteries mostly originate from differences in layer thicknesses and internal resistance.…”

Section: Cell Design and Practical Energy Densitymentioning

confidence: 99%

See 3 more Smart Citations

From Lithium‐Metal toward Anode‐Free Solid‐State Batteries: Current Developments, Issues, and Challenges

Heubner

Maletti

Auer

et al. 2021

Adv Funct Materials

136

104

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Section: Manufacturing and Costsmentioning

confidence: 99%

Section: Manufacturing and Costsmentioning

confidence: 99%

Section: Manufacturing and Costsmentioning

confidence: 99%

Section: Cell Design and Practical Energy Densitymentioning

confidence: 99%

See 2 more Smart Citations

From Lithium‐Metal toward Anode‐Free Solid‐State Batteries: Current Developments, Issues, and Challenges

Heubner

Maletti

Auer

et al. 2021

Adv Funct Materials

136

104

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show abstract

“…Thus, some strategies attempt to replace the liquid electrolytes with solid-state electrolytes to suppress the growth of lithium dendrites and improve the safety, while the low ionic conductivity and poor interfacial compatibility hinder their depth development. [24][25][26][27] In that case, many researchers focus their attention on the modification of 3D hosts of metallic lithium. Modified 3D hosts can significantly reduce local current density, ease volume expansion, promote uniform plating/stripping of lithium, inhibit dendrite growth, and greatly improve electrochemical performance eventually.…”

mentioning

confidence: 99%

A Highly Reversible Lithium Metal Anode by Constructing Lithiophilic Bi‐Nanosheets

Liu

Zhang

et al. 2021

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As a favorable candidate for the next‐generation anode materials, metallic lithium is faced with two crucial problems: uncontrollable lithium plating/stripping process and huge volume expansion during cycling. Herein, a 3D lithiophilic skeleton modified with nanoscale Bi sheets (Ni@Bi Foam, i.e., NBF) through one‐step facile substitution reaction is constructed. Benefiting from the nanoscale modification, smooth and dense lithiophilic Li3Bi layer is in situ formed, which improves the uniform deposition of Li subsequently. Meanwhile, the 3D structure inhibits the growth of Li dendrites effectively by reducing local areal current density. Consequently, the NBF exhibits outstanding cycling stability with a high average Coulombic efficiency of 98.46% at 1 mA cm−2 with 1 mAh cm−2 (>500 cycles). Symmetrical cell with NBF exhibits a high reversibility at 1 mA cm−2 with 1 mAh cm−2 (>2000 h). Moreover, superior long‐term cycling and rate performance of NBF@Li anode are also acquired when assembled with high areal loading of LiFePO4 (10.1 mg cm−2) cathode (Negative/Positive ratio: 2.91). Even in anode‐free metal lithium batteries, NBF has higher capacity during cycling compared with NF. To conclude, NBF shows excellent electrochemical performance and provides an idea of facile preparation method which can be extend to other metal batteries.

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Self‐Regulation Seaweed‐Like Lithium Metal Anode Enables Stable Cycle Life of Lithium Battery

Wang

Gao

et al. 2021

Adv Funct Materials

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Lithium (Li) metal anodes exhibit intriguing advantages for application in high‐energy‐density batteries. However, the short cycle life and security issues of these anodes induced by the dendrite growth and huge volumetric change of Li severely limit their practical application. Herein, a heuristic method to fabricate a self–supported seaweed‐like Li metal anode directly to improve the cycle life of Li metal batteries, is reported. The unique seaweed‐like morphology of the Li anode facilitates the dispersion of the local current density, impeding the uneven growth of Li dendrites, and remits the volume expansion of the anode, leading to excellent cycle performance. The as‐prepared Li metal anode exhibits excellent plating–stripping stability over 600 cycles at high current density of 2 mA cm−2 and delivers excellent stability even with the Li4Ti5O12 cathode in the full cell. This study provides a facile strategy to prepare stable and dendrite‐free Li anodes by controlling the morphology of Li metal. Thus, this study can further inspire new research ideas for preparing stable Li metal anodes.

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Toward the Scale‐Up of Solid‐State Lithium Metal Batteries: The Gaps between Lab‐Level Cells and Practical Large‐Format Batteries

Cited by 121 publications

References 308 publications

From Lithium‐Metal toward Anode‐Free Solid‐State Batteries: Current Developments, Issues, and Challenges

From Lithium‐Metal toward Anode‐Free Solid‐State Batteries: Current Developments, Issues, and Challenges

A Highly Reversible Lithium Metal Anode by Constructing Lithiophilic Bi‐Nanosheets

Self‐Regulation Seaweed‐Like Lithium Metal Anode Enables Stable Cycle Life of Lithium Battery

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