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Kinetic understanding of lithium metal electrodeposition for lithium anodes
Physical Chemistry Chemical PhysicsA comprehensive understanding of the kinetic impacts on lithium deposition and growth is outlined, along with a discussion of diverse strategies for kinetic control and regulation of lithium deposition behaviors.
Rong Fang +4 more
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Interphase Design for Lithium-Metal Anodes
Journal of the American Chemical SocietyElectrode-electrolyte interphases are critical determinants of the reversibility and longevity of lithium (Li)-metal batteries (LMBs). However, upon cycling, the inherently delicate interphases, formed from electrolyte decomposition, become vulnerable to chemomechanical degradation and corrosion, resulting in rapid capacity loss and thus short battery ...
Qidi Wang +12 more
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Application of Lithium Metal Anodes
2016Li metal is an ideal anode to replace carbon based anode used in the state of the art Li-ion batteries. It is also widely used in Li-S and Li-air batteries. Although the use of Li metal anodes in these batteries has been limited by Li dendrite growth and the low CE of Li cycling, the stability of Li metal anodes is much different when used in different
Ji-Guang Zhang +2 more
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Fluorescence Probing of Active Lithium Distribution in Lithium Metal Anodes
Angewandte Chemie International Edition, 2019AbstractThe uncontrollable growth of Li dendrites and the accumulation of byproducts are two severe concerns for lithium metal batteries, which leads to safety hazards and a low Coulombic efficiency. To investigate the deterioration of the cell, it is important to figure out the distribution of active Li species on the anode surface and distinguish Li ...
Xiangyang Cheng +8 more
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Stable lithium metal anode enabled by lithium metal partial alloying
Nano Energy, 2019Abstract The practical application of lithium (Li) metal anodes is critical for the next generation high energy density batteries. However, the mainstream challenge of Li dendrites formation that affects the cycle performance and safety of the battery still needs to be addressed.
Hailong Qiu +5 more
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Surface Modification of Lithium Metal as an Anode in Lithium Metal‐Based Batteries
SmallABSTRACT The growing demand for high‐energy–density storage systems, driven by the rapid expansion of electric vehicles (EVs) and portable electronics, has recognized lithium metal anode (LMA) as a promising candidate in next‐generation rechargeable batteries.
Osman Goni Shovon +4 more
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Rechargeable lithium battery anodes: alternatives to metallic lithium
Journal of Applied Electrochemistry, 1993This review is concerned with alternatives to metallic lithium for use in rechargeable lithium batteries. Emphasis is placed on the use of various materials and combinations of materials in different types of electrodes rather than on the properties of the materials themselves.
D. Fauteux, R. Koksbang
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Theoretical Study of Lithium Electrodeposition on Lithium Metal Anodes
ECS Meeting Abstracts, 2019Lithium metal anode is among the most promising anodes for the next generation of batteries due to its high theoretical energy density and capacity. Challenges such as high reactivity and lithium dendrite formation have kept lithium metal anodes away from practical applications in portable electronics and electric/hybrid vehicles.
M Stefany Angarita-Gomez +1 more
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Solid Electrolyte Interphase on Lithium Metal Anodes
ChemSusChemAbstract Lithium metal batteries (LMBs) represent the most promising next‐generation high‐energy density batteries. The solid electrolyte interphase (SEI) film on the lithium metal anode plays a crucial role in regulating lithium deposition and improving the cycling performance of LMBs.
Zhichuan Shen +5 more
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Morphological Transitions on Lithium Metal Anodes
Journal of The Electrochemical Society, 2009Coin cells were prepared using a metallic lithium anode, a Li{sub 4}Ti{sub 5}O{sub 12} cathode, and a 1.2 M LiPF{sub 6}/ethylene carbonate:ethyl methyl carbonate (30:70 wt %) electrolyte. The cells were cycled galvanostatically between 1 and 2 V vs Li/Li{sup +} (i=2.0 mA/cm{sup 2}) at a 2C rate.
Carmen M. López +2 more
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