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The Lithium Ion

2016
For more than a century, lithium was considered an oddity and a laboratory curiosity of very limited use. Now, however, lithium is regarded as one of the most critical of the elements. It is strategically and economically crucial in many sectors of human activity, including nuclear, medicine, energy, lubricants, metallurgy, polymers and glass sectors ...
Larcher, Dominique, Tarascon, Jean-Marie
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Recurrent Depressions and the Lithium Ion

American Journal of Psychiatry, 1968
Lithium was successfully used to treat five patients with recurrent depressions, three of whom had typical manic-depressive illnesses. Their clinical and also their characteristic subjective responses to lithium establish a very suggestive relationship between illnesses previously believed on observational grounds alone to be related. Some term such as
W L, Dyson, M, Mendelson
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Lithium-Ion Battery Systems

Proceedings of the IEEE, 2014
The production of lithium-ion (Li-ion) batteries has been continually increasing since their first introduction into the market in 1991 because of their excellent performance, which is related to their high specific energy, energy density, specific power, efficiency, and long life. Li-ion batteries were first used for consumer electronics products such
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Doping of Glass with Lithium Ion

Analytical Chemistry, 2005
Doping of glass with lithium ion can be accomplished by exposing the glass to a solution of organic solvent containing a soluble lithium ion salt, such as LiBr and a small amount of water. Under such conditions, the activity of solvated Li+ is very high causing it to partition into the hydrated glass surface.
Greg, Moakes   +2 more
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Nanocomposite Lithium Ion Conducting Membranes

Annals of the New York Academy of Sciences, 2003
Abstract: This review describes the properties and characteristics of a class of membranes formed by blends of a lithium salt, LiX, where X is preferably a large soft anion, such as ClO4 or N(CF3SO2)2, and a high molecular weight polymer containing Li+‐coordinating group, such as polyethylene oxide (PEO) with the dispersion of selected ceramic powders,
CROCE, Fausto, B. Scrosati
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Magnetism of Hydrogen and Lithium Ions

Nature, 1951
IN the free state, the hydrogen ion, H+, can clearly exhibit no magnetism, and the lithium ion, Li+, will possess a small diamagnetism. It has often been pointed out that, in solids or in solutions, these ions should not behave in this fashion, but Would most likely give rise to a paramagnetic effect in addition.
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Energetical Modeling of Lithium-Ion Batteries

2007 IEEE Industry Applications Annual Meeting, 2007
All electrochemical batteries are characterized by an electrical behavior which depends on temperature, state of charge and current. In the case of lithium-ion accumulators, the energetical behavior is moreover deeply marked by line effects, due to the porosity of both electrodes. This paper deals with investigations on accurate energetical modeling of
Urbain, Matthieu   +2 more
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Lithium ion sources

Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 2014
A 10.9 cm diameter lithium alumino-silicate ion source has been chosen as a source of 100 mA lithium ion current for the Neutralized Drift Compression Experiment (NDCX-II) at LBNL. Research and development was carried out on lithium alumino-silicate ion sources prior to NDCX-II source fabrication.
Prabir K. Roy   +6 more
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Transport Energy – Lithium Ion Batteries

2014
This chapter focuses on the technological status and most common chemistries of lithium ion batteries. According to IEA, in the year 2012, the global stock of plug-in hybrid electric vehicles (PEHVs) and electric vehicles (EVs) amounted to more than 18 0000, representing only 0.02 % of all vehicles.
Salminen, Justin   +5 more
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Nanotechnology for Lithium-Ion Batteries

2013
Introduction.- Inverse opal nanoarchitectures as Lithium-ion battery materials.- Nano-engineered silicon anodes for Lithium-ion rechargeable batteries.- Tin-based anode materials for Li-ion batteries.- Beyond intercalation: Nanoscaled enabled conversion anode materials for Li-ion batteries.- Graphene-based composite anodes for Lithium-ion batteries ...
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