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Manganese oxide thermal conductivity

Preliminary electrochemical tests of materials obtained have been performed in two types of cells. Primary discharge measurements have been executed in standard 2325 coin-type cells (23 mm diameter and 2.5 mm height) with an electrolyte based on propylene carbonate - dimethoxyethane solution of LiC104. Cathode materials have been prepared from thermally treated amorphous manganese oxide in question (0.70 0.02g, 85wt%.) mixed with a conductive additive (10 % wt.) and a binder (5wt%). Lithium anodes of 0.45 mm thickness have been of slightly excess mass if compared to the stoichiometric amount, so as to ensure maximal possible capacity of a cell and full consumption of the cathode material. [Pg.484]

Promising results have also been obtained in cycling ability studies performed in model coin-type cells with this same amorphous cathode material. Moreover, it has been found that either thermally treated or even initial amorphous manganese oxide exhibit satisfactory results. Cyclic voltammetric studies have been carried out with the LP-30 electrolyte (Merck). Cathode materials have been prepared from amorphous manganese oxide in question (80wt%) mixed with a conductive additive (10wt%) and a... [Pg.484]

Heat of combustion, thermal conductivity, surface area and other factors influencing pyrophoricity of aluminium, cobalt, iron, magnesium and nickel powders are discussed [4], The relationship between heat of formation of the metal oxide and particle size of metals in pyrophoric powders is discussed for several metals and alloys including copper [5], Further work on the relationship of surface area and ignition temperature for copper, manganese and silicon [6], and for iron and titanium [7] was reported. The latter also includes a simple calorimetric test to determine ignition temperature. [Pg.364]

Several methods have been used to produce different types of OL-1, OMS-1, and OMS-2 materials. The materials that are produced by various methods lead to vastly different materials, that have unique chemical and physical properties. Some of the properties that can be controlled are particle size, color, morphology, average manganese oxidation state, thermal stability, ion-exchange capacity, electrical conductivity, magnetic properties, crystallinity, defect density, desorption of oxygen, and catalytic properties. Table IV summarizes 16 different classes of OMS-1, OMS-2, OL-1, and amorphous manganese oxide (AMO) materials that we have prepared. These materials are separated into different classes because they show different crystalline, chemical and physical properties. For the case of OMS-1 these materials... [Pg.59]

See other pages where Manganese oxide thermal conductivity is mentioned: [Pg.459]    [Pg.1817]    [Pg.67]    [Pg.1816]    [Pg.653]    [Pg.645]    [Pg.699]    [Pg.185]    [Pg.205]    [Pg.632]    [Pg.242]    [Pg.727]    [Pg.705]    [Pg.691]    [Pg.628]    [Pg.725]    [Pg.645]    [Pg.61]    [Pg.51]    [Pg.1065]    [Pg.331]    [Pg.313]    [Pg.331]    [Pg.29]    [Pg.143]    [Pg.493]    [Pg.616]    [Pg.359]    [Pg.713]    [Pg.56]    [Pg.9057]    [Pg.206]    [Pg.1079]    [Pg.35]    [Pg.744]    [Pg.210]    [Pg.305]   
See also in sourсe #XX -- [ Pg.326 ]



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Conductivity oxides

Manganese oxidation

Manganese-oxidizing

Oxidants manganese

Oxide thermal conductivity

Thermal oxidation

Thermal oxides

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