Lithium-manganese dioxide cell

Fig. 23. Cutaway view of (a) 2016-size Eveieady lithium manganese dioxide coin cell, and (b) jelly toll cylindrical lithium manganese dioxide cell (28).

Lithium-magnesium alloys, 15 135 Lithium manganate(V), 15 592 Lithium-manganese dioxide cells, 3 461 characteristics, 3 462t Lithium metaborate, 15 137 Lithium metaborate octahydrate, 4 277 Lithium metal, 15 132 uses for, 15 134 Lithium metal films, 15 128 Lithium methoxide, 15 148 Lithium nickelate, 15 142 Lithium niobate, 15 141 17 153... 

Solid Cathode Cells. Solid cathode cells include lithium-manganese dioxide cells, lithium carbon inonofluoridc cells, lithium iron disulfide cells, and lithium—iodine cells. 

Lithium batteries with a manganese dioxide cathode are also used when reduction in size and weight is important, such as for powering 35 mm flash cameras. The lithium-manganese dioxide cell and reaction may be written as ... 

Li/Mn02 Cells The lithium/ manganese dioxide cells are the most popular cells produced in the solid cathode... 

Figure 11.4. Typical discharge curves of lithium-manganese dioxide cell. C-rate 1 — C/5, 2 - C/2.

Root MJ (2010) Lithium-manganese dioxide cells for implantable defibrillators - discharge voltage models. J Power Sources 195 5089-5093... 

Alkaline Primary Cells, Fig. 8 Capacity loss on storage of various miniature alkaline cell systems compared to carbon-zinc and lithium-manganese dioxide cells. The lithium-based cells have significantly better storage characteristics compared to alkaline and carbon-zinc cells... 

Figure 18.6 Cross section of a lithium/manganese dioxide cell (Varta).

The present situation is made easier by the comparably low turnover of lithium batteries. Partly batteries are disposed of as harmless in normal sanitary landfills (like primary lithium/manganese dioxide cells), partly more active systems are brought to special landfills (like lithium/sulfur dioxide together with neutralizing amounts of limestone), and partly batteries are burned in special ovens in combination with oil (like lithium/thionylchloride batteries). 

Table 5.2 Characteristics of a Lithium-Manganese-Dioxide Cell...

Table 9.8 Comparisonof ene y density of lithium-manganese dioxide cells with conventionaltypes...

The capacity or service life of lithium-manganese dioxide cells, normalized for a 1 g and a 1 cm cell, at various temperatures and loads, is summarized in Figure 30.50. These data can be used to calculate the performance of a given cell or to select a cell of suitable size or weight for a particular application. It is to be noted that, since the actual cell performance is dependent on cell size and construction and other such factors, these data are only approximate. These cells are a relatively new type and consequently only limited storage life data are available. Projections suggest that cells will provide 85% of initial capacity after 6 years storage at 20 C. 

Discharge characteristics of Duracell cylindrical and low-rate button lithium-manganese dioxide cells are shown, respectively, in Figures 56.11 and 56.12. 

Figure 56.11 Discharge characteristics of a Duracell DL jN, 3V, leOmAh cylindrical lithium-manganese dioxide cell. Current at 2.7 V (Courtesy of Duracell)...

Table 56.13 Lithium-manganese dioxide cells and batteries supplied by Duracell...

Table 56.14 Operating and storage temperaturesef SAFT lithium-manganese dioxide cells...

Eagle Picher (US) are also major suppliers of lithium-manganese dioxide cells. Sanyo (Japan) has licensed production of lithium-manganese dioxide cells to the following companies ... 

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