Results 11 to 20 of about 609,015 (308)
Nature Communications, 2022 High-voltage non-aqueous lithium metal batteries suffer from poor cycling stability due to the presence of impurities in the electrolyte solution. Here, the authors report lithium hexamethyldisilazide to scavenge HF and H2O, prevent the Ni dissolution ...
Danfeng Zhang +14 more
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Progress and Prospects of Inorganic Solid‐State Electrolyte‐Based All‐Solid‐State Pouch Cells
Advances in Materials, 2022 All‐solid‐state batteries have piqued global research interest because of their unprecedented safety and high energy density. Significant advances have been made in achieving high room‐temperature ionic conductivity and good air stability of solid‐state ...
Changhong Wang +3 more
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Progress and perspective of Li1 + xAlxTi2‐x(PO4)3 ceramic electrolyte in lithium batteries
InfoMat, 2021 The replacement of liquid organic electrolytes with solid‐state electrolytes (SSEs) is a feasible way to solve the safety issues and improve the energy density of lithium batteries. Developing SSEs materials that can well match with high‐voltage cathodes
Ke Yang +4 more
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Role of Interfacial Defects on Electro–Chemo–Mechanical Failure of Solid‐State Electrolyte
Advances in Materials, 2023 High‐stress field generated by electroplating of lithium (Li) in pre‐existing defects is the main reason for mechanical failure of solid‐state electrolyte because it drives crack propagation in electrolyte, followed by Li filament growth inside and even ...
Yangyang Liu +5 more
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Electrode Potentials Part 2: Nonaqueous and Solid-State Systems
Electrochemistry, 2022 This comprehensive paper, Electrode Potentials Part 2, is a continuation of Electrode Potentials Part 1: Fundamentals and Aqueous Systems. Determining the electrode potential is crucial for understanding the nature of the electrochemical properties of ...
Jinkwang HWANG +4 more
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Advanced Functional Materials, 2023 The dry process is a promising fabrication method for all‐solid‐state batteries (ASSBs) to eliminate energy‐intense drying and solvent recovery steps and to prevent degradation of solid‐state electrolytes (SSEs) in the wet process. While previous studies
Dong Ju Lee +13 more
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Review of various sulfide electrolyte types for solid-state lithium-ion batteries
Open Engineering, 2022 The high sulfide ion polarization is known to cause increased ionic conductivity in the solid sulfide-type electrolytes. Three groups of sulfide-based solid-state electrolytes, namely, Li-P-S, Li6PS5X (X: Cl, Br, and I), and LixMPxSx (M: Sn, Si, and Al ...
Suci Windhu Griyasti +5 more
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Hard Carbon–Sulfide Solid Electrolyte Interface in All-Solid-State Sodium Batteries
Electrochemistry, 2023 Hard carbon is a promising negative electrode material for sodium-ion batteries that operate at low potentials. However, reversible and high-capacity charging and discharging in all-solid-state sodium batteries with hard carbon electrodes using sulfide ...
Wataru YOSHIDA +5 more
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Mechanical Failure of Solid‐State Electrolyte Rooted in Synergy of Interfacial and Internal Defects
Advanced Energy Materials, 2023 The mechanical failure of solid‐state electrolytes induced by the growth of the lithium metal anode hinders the development of solid‐state Li metal batteries with good safety and high energy density, and thus the understanding of the failure mechanism is
Shizhao Xiong +6 more
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Research progress of cathode/electrolyte interface in solid-state batteries
Cailiao gongcheng, 2022 Lithium-ion battery is an ideal power source for portable electronic products, electric vehicles and smart grid. At present, there are still some problems, such as safety and short service life, in lithium-ion batteries using organic liquid electrolyte ...
ZHANG Anbang +4 more
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