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A Dendrite‐Free Lithium/Carbon Nanotube Hybrid for Lithium‐Metal Batteries
Advanced Materials, 2020AbstractLithium (Li) metal is promising in the next‐generation energy storage systems. However, its practical application is still hindered by the poor cycling performance and serious safety issues for the consequence of dendritic Li. Herein, a dendrite‐free Li/carbon nanotube (CNT) hybrid is proposed, which is fabricated by direct coating molten Li on
Zhi Yong Wang +8 more
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Mechanics of Amorphous Lithium Dendrites
ECS Meeting Abstracts, 2017The formation of dendrites is a critical drawback for the utilization of Li and other metals in secondary batteries. These emorphous crystals can pierce into the polymer electrolyte and short the cell. Therefore the design/selection criterion requires the dendrite-polymer mechanical compatibility.
Asghar Aryanfar +2 more
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Fe3C/nanocarbon‐Enabled Lithium Dendrite Mitigation in Lithium–Sulfur batteries
Small, 2023AbstractLithium dendrite‐induced short circuits and material loss are two major obstacles to the commercialization of lithium–sulfur (Li−S) batteries. Here, a nanocarbon composite consisting of cotton‐derived Fe3C‐encapsulated multiwalled carbon nanotubes (Fe3C‐MWCNTs) and graphene effectively traps polysulfides to suppress lithium dendrite growth is ...
Ruoxi Chen, Yucheng Zhou, Xiaodong Li
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Interlayered Dendrite‐Free Lithium Plating for High‐Performance Lithium‐Metal Batteries
Advanced Materials, 2019AbstractFor its high theoretical capacity and low redox potential, Li metal is considered to be one of the most promising anode materials for next‐generation batteries. However, practical application of a Li‐metal anode is impeded by Li dendrites, which are generated during the cycling of Li plating/stripping, leading to safety issues.
Ying Xu, Tao Li, Liping Wang, Yijin Kang
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Double-Edged Effect of Temperature on Lithium Dendrites
ACS Applied Materials & Interfaces, 2020Lithium metal, although attracting renewed interest for the next revolution in energy storage, continues to be challenged with the detrimental dendrite formation. Recent experimental reports have demonstrated the contrasting impact of thermal attributes on the electrodeposition morphology, showcasing the alleviation and/or aggravation of dendrite ...
Bairav Sabarish Vishnugopi +3 more
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Solid‐State Electrolyte Design for Lithium Dendrite Suppression
Advanced Materials, 2020AbstractAll‐solid‐state Li metal batteries have attracted extensive attention due to their high safety and high energy density. However, Li dendrite growth in solid‐state electrolytes (SSEs) still hinders their application. Current efforts mainly aim to reduce the interfacial resistance, neglecting the intrinsic dendrite‐suppression capability of SSEs.
Xiao Ji +7 more
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Lithium Dendrite Growth Through Polymer Electrolytes
ECS Meeting Abstracts, 2013Abstract not Available.
Nitash P. Balsara, Katherine J. Harry
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Surface dendrite in lithium niobate crystals
Materials Research Bulletin, 1973Abstract The growth of a surface dendrite of a complex nature has been observed in lithium niobate grown perpendicular to the c-axis. The dendrite limbs in different directions are described and a growth mechanism is suggested. It was found that a small volume of the melt in the crucible and a rapid rate of cooling do not favour the dendritic growth.
K. Singh, K.G. Deshmukh
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How lithium dendrites form in liquid batteries
Science, 2019Studies of interfacial reactions and mass transport may allow safe use of lithium metal ...
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Lithium Dendrites Inhibition via Diffusion Enhancement
Advanced Energy Materials, 2019AbstractThe dendritic structure is a disastrous problem of lithium metal batteries as well as other metal rechargeable batteries. The dendritic structures are usually caused by diffusion limitation. Here, a novel strategy is reported to inhibit lithium dendrites based on the understanding of their formation mechanism.
Yongxiu Chen +3 more
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