Revisiting the Corrosion of the Aluminum Current Collector in Lithium
DOI: 10.1021/acs.jpclett.6b02933 Corpus ID: 46803844; Revisiting the Corrosion of the Aluminum Current Collector in Lithium-Ion Batteries. @article{Ma2017RevisitingTC, title={Revisiting the Corrosion of the Aluminum Current Collector in Lithium-Ion Batteries.}, author={Tian-Yi Ma and Gui‐Liang Xu and Yan Li and Li Wang and
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Revisiting the role of Zr doping in Ni-rich layered cathodes for
Journal Article: Revisiting the role of Zr doping in Ni-rich layered cathodes for lithium-ion batteries Layered Li x Ni y Mn y Co 1-2 y O 2 Cathodes for Lithium Ion Batteries: Understanding Local Structure via Magnetic Properties.
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Revisiting the corrosion mechanism of LiFSI based electrolytes in
The compositions of electrolytes have a critical influence on the interface electrochemical behavior, especially lithium salts [13, 14].LiPF 6 is wildly used in the Li-ions batteries, but it cannot be well compatible with Li anode because hydrogen fluoride (HF) and other products from pyrolysis and hydrolysis of LiPF 6, leading to a series of side reactions [15, 16].
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Revisiting Classical Rocking Chair Lithium-Ion Battery
Revisiting Classical Rocking Chair Lithium-Ion Battery Abstract: Rechargeable energy storage systems become an indispensable element to drive the electrified modern society as attributed to the groundbreaking develop-ment of rocking chair lithium-ion batteries (LIBs). For the past thirty years, LIBs sig-
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Revisiting the origin of cycling enhanced capacity of Fe3O4 based
Revisiting the origin of cycling enhanced capacity of Fe 3 O 4 based nanostructured electrode for lithium ion batteries. Author links open overlay panel Yuan Huang a, Zihan Xu a, Jiangquan Mai a, Magnetite (Fe 3 O 4) is a promising electrode material for lithium ion batteries (LIBs)
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Revisiting Classical Rocking Chair Lithium-Ion Battery
This review covers the basic study on the rocking chair LIBs regarding the charge storage mechanism across the principal battery components of the anode, cathode,
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Mechanism, quantitative characterization, and inhibition of
<p>Rechargeable lithium batteries with long calendar life are pivotal in the pursuit of non-fossil and wireless society as energy storage devices. However, corrosion has severely plagued the calendar life of lithium batteries. The corrosion in batteries mainly occurs between electrode materials and electrolytes, which results in constant consumption of active materials and
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High-throughput and high-performance lithium-ion batteries via
Lithium-ion batteries (LIBs) have been playing an essential role in energy storage and empowering electric vehicles (EVs) by alleviating the CO 2 emission from the fossil fuel -based vehicles [1], [2]. However, conventional LIB electrodes are manufactured through a wet slurry processing in a roll-to-roll (R2R) manner, which uses N-methyl pyrrolidone (NMP) as a
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Revisiting Metal Fluorides as Lithium-ion Battery Cathodes
by revisiting prior experimental studies of FeF2 and CuF2. Metal fluoride lithiation is instead dominated by diffusion-controlled displacement mechanisms, a clear topological relationship
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Revisiting Polytetrafluorethylene Binder for
Revisiting Polytetrafluorethylene Binder for Solvent-Free Lithium-Ion Battery Anode Fabrication . by Yang Zhang. Yang Zhang. SciProfiles Lithium-ion batteries (LIBs)
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Revisiting aluminum current collector in lithium-ion batteries
Revisiting aluminum current collector in lithium-ion batteries: Corrosion and countermeasures. Author links open overlay panel Shanglin Yang, Jinyan Zhong, Songmei Li, Bin Li. Show more. Add to Mendeley. Since the successful commercialization in the 1990s, lithium-ion batteries (LIBs) have supplanted traditional lead-acid batteries due to
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Revisiting Electrochemical Techniques to
Lithium-ion batteries (LiBs) have gained a worldwide position as energy storage devices due to their high energy density, power density and cycle life.
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Revisiting Lithium
Revisiting Lithium- and Sodium-Ion Storage in Hard Carbon Anodes. Sulfur-doped hard carbon hybrid anodes with dual lithium-ion/metal storage bifunctionality for high-energy-density lithium-ion batteries. Carbon Energy (IF 19.5) Pub Date: 2022-11-24, DOI: 10.1002/cey2.288
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Revisiting LiClO4 as an Electrolyte for Rechargeable Lithium-Ion
In lithium-ion batteries, the choice of electrolyte solution formulation is an important consideration for both performance and safety. The commonly used anode for this
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Revisiting on the effect and role of TiO2 layer thickness on SnO2
Revisiting on the effect and role of TiO 2 layer thickness on SnO 2 for enhanced electrochemical performance for lithium-ion batteries. Author links open overlay panel Jun Young Cheong a, Joon Ha Chang a b, Chanhoon Kim a, Frank Jaksoni Mweta a b, Ji-Won Jung a, Jeong Yong Lee a b, Il-Doo Kim a b.
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Solvent-free lithium iron phosphate cathode fabrication with
Estimation of lithium-ion batteries state-condition in electric vehicle applications: issues and state of the art. Electronics (Basel), 10 (2021), p. 1588. Revisiting polytetrafluorethylene binder for solvent-free lithium-ion battery anode fabrication. Batteries, 8 (2022), p. 57. View PDF View article Google Scholar
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Revisiting Olivine Phosphate and Blend Cathodes in Lithium Ion
Lithium-ion batteries (LIBs) with excellent performance are widely used in portable electronics and electric vehicles (EVs), but frequent fires and explosions limit their further and more
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Revisiting the Roles of Natural Graphite in Ongoing
Graphite, commonly including artificial graphite and natural graphite (NG), possesses a relatively high theoretical capacity of 372 mA h g –1 and appropriate lithiation/de-lithiation potential, and has been extensively used
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Revisiting LiClO4 as an Electrolyte for
Lithium-Ion Batteries Rotem Marom, a Ortal Haik, a Doron Aurbach, a, *, z and Ion C. Halalay b, ** a Department of Chemistry, Bar-Ilan University, Ramat Gan 52900, Israel
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Revisiting the role of Zr doping in Ni-rich layered cathode for lithium
Request PDF | Revisiting the role of Zr doping in Ni-rich layered cathode for lithium-ion batteries | The realization of high performance Ni-rich layered cathodes remains a challenge because of
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Revisiting the energy efficiency and (potential) full-cell
Revisiting the energy efficiency and (potential) full-cell performance of lithium-ion batteries employing conversion/alloying-type negative electrodes. From a practical point of view, this is a very important finding, as conventional lithium-ion batteries are always cathode-limited, in fact, while the use of the complete voltage range from
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Revisiting aluminum current collector in lithium-ion batteries
In this review, the corrosion failure behavior of the cathode aluminum current collector in lithium-ion batteries with organic electrolytes is comprehensively analyzed, and the
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Revisiting polymeric single lithium-ion conductors as
This exceptional single ion transport behavior of polymeric SLICs, in combination with their solid-state nature, flexibility and facile processability, brings remarkable benefits to the battery structure and performance, which lie far beyond those
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Revisiting Classical Rocking Chair Lithium-Ion Battery
Rechargeable energy storage systems become an indispensable element to drive the electrified modern society as attributed to the groundbreaking development of rocking chair lithium-ion batteries (LIBs). For the past thirty years, LIBs significantly advance in their building materials and architectures that continue to shape forthcoming electronic applications
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Restructuring the lithium-ion battery: A perspective on electrode
Highlights • Architecture design strategies of lithium-ion battery electrodes are summarized. • Templating, gradient, and freestanding electrode design approaches are
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Revisiting Polytetrafluorethylene Binder for Solvent-Free Lithium
Post-Li chemistries like Al or Zn are emerging as promising candidates for next-generation rechargeable batteries [31, 32]. The application of the method also could be used
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Revisiting LiClO4 as an electrolyte for Li-ion battery: Effect of
A mixture of 0.5 M LiClO 4 in 80% tetramethylsulfone (TMS) and 20% propylene carbonate (PC) was investigated through classical molecular dynamics simulations to understand properties that could make this a possible candidate for a better electrolyte for lithium-ion battery. The structural analysis through radial distribution function (RDF) reveals the strong
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Revisiting ether electrolytes for high-voltage sodium-ion batteries
Lithium-ion batteries (LIBs) have powered our daily life since their commercial launch in 1990s. In the past decades, sodium-ion batteries (SIBs) have aroused great interest due to their advantage in cost and abundance over LIBs [1, 2].SIBs operate following a rocking-chair mechanism where the cathode and anode reversibly insert/extract sodium ions, and the
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Revisiting aluminum current collector in lithium-ion batteries
DOI: 10.1016/j.jechem.2023.09.036 Corpus ID: 264068761; Revisiting aluminum current collector in lithium-ion batteries: corrosion and countermeasures @article{Yang2023RevisitingAC, title={Revisiting aluminum current collector in lithium-ion batteries: corrosion and countermeasures}, author={Shanglin Yang and Jinyan Zhong and Song-yan Li and Bin Li},
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Revisiting the origin of cycling enhanced capacity
Revisiting the origin of cycling enhanced capacity of Fe 3 O 4 based nanostructured electrode for lithium ion batteries. Yuan Huang, Zihan Xu, Jiangquan Mai, Tsz Ki Lau, Xinhui Lu, Yao Jane Hsu, Yongsheng Chen, Alex Chinghuan Lee, Yanglong Hou, Ying Shirley Meng, Quan Li / Revisiting the origin of cycling enhanced capacity of Fe 3 O 4 based
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Revisiting the Corrosion of the Aluminum Current
Revisiting the stability of aluminum current collectors in carbonate electrolytes for High-Voltage Li-ion batteries. Chemical Engineering Science 2023 Corrosion study of nickel-coated copper and chromate
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Revisiting Classical Rocking Chair Lithium-Ion Battery
Finally, we shortly outline the practical consideration of emerging battery systems such as all-solid-state batteries (ASSBs), lithium-sulfur (Li-S), or dual-ion batteries (DIBs) that should be
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Revisiting Metal Fluorides as Lithium-ion Battery Cathodes
Revisiting Metal Fluorides as Lithium-ion Battery Cathodes Xiao Hua 1,2 3*, Alexander S. Eggeman 4,5, Elizabeth Castillo-Martínez 1,6, Rosa Robert 1, Harry S. Geddes 3, Ziheng Lu 4, Chris J. 8Pickard 4,7, Wei Meng 1, Kamila M. Wiaderek, Nathalie
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Revisiting lithium-storage mechanisms of molybdenum disulfide
With the development of energy storage technology, lithium-ion batteries have achieved a great success in the commercial application and almost dominated the battery market worldwide [1, 2]. Nowadays, LIBs have been widely used in the field of digital devices and electric vehicles, which effectively alleviates energy and environmental problems [3] .
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Revisiting Classical Rocking Chair Lithium-Ion Battery
This review covers the basic study on the rocking chair LIBs regarding the charge storage mechanism across the principal battery components of the anode, cathode, and
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Natural graphite anode for advanced lithium-ion Batteries:
Thus, advancing lithium-ion battery technology necessitates the design of next-gen anode materials that exhibit high reversible capacity and stable electrochemical performance. Silicon-based anodes are highly promising as next-gen high-energy–density materials for LIBs. Revisiting the roles of natural graphite in ongoing lithium‐ion
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Revisiting metal fluorides as lithium-ion battery cathodes
Journal Article: Revisiting metal fluorides as lithium-ion battery cathodes Metal fluorides, promising lithium-ion battery cathode materials, have been classified as conversion materials due to the reconstructive phase transitions widely presumed to
View more6 FAQs about [Revisiting lithium-ion batteries]
Why are electrolyte solutions important in lithium-ion batteries?
Electrolyte solutions are key components in electrochemical devices, especially when the electrodes comprise highly reactive materials. In lithium-ion batteries, the choice of electrolyte solution formulation is an important consideration for both performance and safety.
Is graphite a lithium ion battery?
Learn more. Graphite, commonly including artificial graphite and natural graphite (NG), possesses a relatively high theoretical capacity of 372 mA h g –1 and appropriate lithiation/de-lithiation potential, and has been extensively used as the anode of lithium-ion batteries (LIBs).
Does cathode aluminum current collector corrosion a lithium-ion battery?
In this review, the corrosion failure behavior of the cathode aluminum current collector in lithium-ion batteries with organic electrolytes is comprehensively analyzed, and the corresponding protective strategies are systematically summarized. 1. Introduction Energy is a pivotal driver for advancing social and economic progress.
How to reduce the manufacturing cost of lithium ion batteries?
The cost of batteries mainly consists of two parts, i.e., raw materials and manufacturing costs. Reducing manufacturing energy consumption and increasing electrode thickness are two effective methods to lower the manufacturing cost of LIBs .
What are the design strategies for lithium-ion battery electrodes?
Architecture design strategies of lithium-ion battery electrodes are summarized. Templating, gradient, and freestanding electrode design approaches are reviewed. Process tunability, scalability, and material compatibility is critically assessed. Challenges and perspective on the future electrode design platforms are outlined.
What are lithium ion batteries?
1. Introduction Lithium-ion batteries (LIBs) dominate the market of portable consumer electronic devices since SONY Corporation launched the first commercial product in the 1990s. As the most studied energy storage devices, LIBs have attracted more and more attention.
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