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A lithium-titanate battery is a modified lithium-ion battery that uses lithium-titanate nanocrystals, instead of carbon, on the surface of its anode.This gives the anode a surface area of about 100 square meters per gram, compared with 3 square meters per gram for carbon, allowing electrons to enter and leave the anode quickly.
The Toshiba 4S (Ultra super safe, Small and Simple) is a micro sodium-cooled nuclear fission reactor design. General description. Cross-sectional image of the 4S design.
CR17345 (lithium) 5018LC (lithium) 1,500 (lithium) 700 (Li–ion rechargeable) 3 (lithium) 3.6 (Li-ion) Cylinder +: Nub cylinder end −: Flat opposite end: H: 34.5 mm Ø: 17 mm [134] A lithium primary battery, not interchangeable with zinc types. A rechargeable lithium-ion version is available in the same size and is interchangeable in some uses.
Toshiba Data Corporation; ... In April 2016, Toshiba recalled 100,000 faulty laptop lithium-ion batteries, ... 4K Ultra HD (3840×2160p) televisions provides four ...
A stack of Satellite Pro 470CDTs. Toshiba Information Systems introduced the Satellite Pro 400 series in June 1995, starting with the 400CDT and 400CS models. [1] This was a month after they had announced the Portégé 610CT, the first subnotebook with a Pentium processor, [2] and almost a full year after they had announced the T4900CT, the first notebook-sized laptop with a Pentium processor. [3]
The standard HiNote included a built-in 3.5 inch floppy drive which could be removed and fitted with a second lithium-ion battery pack in its place, while the drive for the Ultra was external only. Both the original HiNotes proper and Ultras included built-in trackballs as its pointing device of choice.
Godshall et al. further identified the similar value of ternary compound lithium-transition metal-oxides such as the spinel LiMn 2 O 4, Li 2 MnO 3, LiMnO 2, LiFeO 2, LiFe 5 O 8, and LiFe 5 O 4 (and later lithium-copper-oxide and lithium-nickel-oxide cathode materials in 1985) [27] Godshall et al. patent U.S. patent 4,340,652 [28] for the use of ...
In current lithium-ion battery technology, lithium diffusion rates are slow. Through nanotechnology, faster diffusion rates can be achieved. Nanoparticles require shorter distances for the transport of electrons, which leads to faster diffusion rates and a higher conductivity, which ultimately leads to a greater power density.