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Cobalt applications

Bath towels (terry), number produced from one bale of cotton, 8 133t Bathtub failure rate, 26 988 Batik printing, 9 219 Batteries, 3 407-434. See also Alkaline cells Carbon-zinc cells Lead-acid batteries Lithium cells Primary batteries Secondary batteries chromium application, 6 565 cobalt applications, 7 247... [Pg.89]

Electroplating, 9 759-838 24 747-750 alkanolamines from olefin oxides and ammonia, 2 137 automated, 9 768, 769 chromium, 6 551-552 cobalt applications, 7 246 in compound semiconductor processing, 22 189... [Pg.309]

Inks, 14 311-336 ball-point, 14 328 cellulose acetates, 5 438 cellulose ester applications, 5 403-404 cobalt applications, 7 244-245 as colloid, 7 272t, 273t color and coloring materials for, 14 316-318... [Pg.475]

Co doped into single crystals of cobalt metal shows a magnetic hyper-fine pattern similar to that of a-iron with a field of —316 kG at room temperature and a value of e qQ of —0-064 mm s [80]. The latter value is nonzero because of the hexagonal symmetry of the cobalt. Application of an external magnetic field parallel and perpendicular to the c axis showed that the external field was strictly additive in both directions. This implies that the hyperfine field is isotropic, an unexpected result when the local environment is non-cubic as seen from the finite quadrupole splitting. [Pg.341]

Field responses to cobalt applications by subterranean clover were reported on sandy soils of South Australia and Western Australia. Later, it was shown that narrow-leafed lupins were even more sensitive to cobalt deficiency. Concentrations of cobalt are less than 1 ppmw in many plant tissues, which is even lower than those of molybdaium, a micronutrient. Cobalt application rates -alsG-arfrqtHte40WrIesS"than-l-4f g/ha.-Although it is possible to prevent cobalt deficiency of livestock by applying cobalt-containing fertilizers to pastures, it may be more practical to supply the cobalt directly to animals in the form of a cobalt bullet given orally to youi animals in cobalt-deficdent areas 133]. [Pg.467]

Besides stmctural variety, chemical diversity has also increased. Pure silicon fonns of zeolite ZSM-5 and ZSM-11, designated silicalite-l [19] and silicahte-2 [20], have been synthesised. A number of other pure silicon analogues of zeolites, called porosils, are known [21]. Various chemical elements other than silicon or aluminium have been incoriDorated into zeolite lattice stmctures [22, 23]. Most important among those from an applications point of view are the incoriDoration of titanium, cobalt, and iron for oxidation catalysts, boron for acid strength variation, and gallium for dehydrogenation/aromatization reactions. In some cases it remains questionable, however, whether incoriDoration into the zeolite lattice stmcture has really occurred. [Pg.2782]

Table 7. Applications of Cobalt-Base Wear-Resistant Alloys... Table 7. Applications of Cobalt-Base Wear-Resistant Alloys...
R. Bmgger, Nickel Plating. A Comprehensive Review of Theory, Practice, Properties, and Applications Including Cobalt Plating, Draper, Teddington, UK, 1970. [Pg.383]

Application. Polyesters are cured by free radicals, most commonly produced by the use of peroxides. A wide range of peroxide initiators (qv) are available for use in curing polyesters. Most peroxide initiators are thermally decomposed into free radicals, and the common initiators used at room temperature requke the use of a promoter such as dimethylaniline or cobalt octoate. [Pg.18]

Metal oxides, sulfides, and hydrides form a transition between acid/base and metal catalysts. They catalyze hydrogenation/dehydro-genation as well as many of the reactions catalyzed by acids, such as cracking and isomerization. Their oxidation activity is related to the possibility of two valence states which allow oxygen to be released and reabsorbed alternately. Common examples are oxides of cobalt, iron, zinc, and chromium and hydrides of precious metals that can release hydrogen readily. Sulfide catalysts are more resistant than metals to the formation of coke deposits and to poisoning by sulfur compounds their main application is in hydrodesulfurization. [Pg.2094]

Concentration limits of the diphosphate-ion, admissible to determination of magnesium and cobalt, manganese and cobalt, zinc and cobalt by spectrophotometric method with application of the l-(2-pyridylazo)-resorcinol (PAR) are presented. Exceeding maintenance of the diphosphate-ion higher admissible supposes a preliminary its separation on the anionite in the H+-form. The optimum conditions of cobalt determination and amount of the PAR, necessary for its full fastening are established on foundation of dependence of optical density of the cobalt complex with PAR from concentration Co + and pH (buffer solutions citrate-ammoniac and acetate-ammoniac). [Pg.182]

Effect of Catalyst The catalysts used in hydrotreating are molybdena on alumina, cobalt molybdate on alumina, nickel molybdate on alumina or nickel tungstate. Which catalyst is used depends on the particular application. Cobalt molybdate catalyst is generally used when sulfur removal is the primary interest. The nickel catalysts find application in the treating of cracked stocks for olefin or aromatic saturation. One preferred application for molybdena catalyst is sweetening, (removal of mercaptans). The molybdena on alumina catalyst is also preferred for reducing the carbon residue of heating oils. [Pg.67]

Carbide-based cermets have particles of carbides of tungsten, chromium, and titanium. Tungsten carbide in a cobalt matrix is used in machine parts requiring very high hardness such as wire-drawing dies, valves, etc. Chromium carbide in a cobalt matrix has high corrosion and abrasion resistance it also has a coefficient of thermal expansion close to that of steel, so is well-suited for use in valves. Titanium carbide in either a nickel or a cobalt matrix is often used in high-temperature applications such as turbine parts. Cermets are also used as nuclear reactor fuel elements and control rods. Fuel elements can be uranium oxide particles in stainless steel ceramic, whereas boron carbide in stainless steel is used for control rods. [Pg.10]

In 1996, consumption in the western world was 14.2 tonnes of rhodium and 3.8 tonnes of iridium. Unquestionably the main uses of rhodium (over 90%) are now catalytic, e.g. for the control of exhaust emissions in the car (automobile) industry and, in the form of phosphine complexes, in hydrogenation and hydroformylation reactions where it is frequently more efficient than the more commonly used cobalt catalysts. Iridium is used in the coating of anodes in chloralkali plant and as a catalyst in the production of acetic acid. It also finds small-scale applications in specialist hard alloys. [Pg.1115]

The first example of homogeneous transition metal catalysis in an ionic liquid was the platinum-catalyzed hydroformylation of ethene in tetraethylammonium trichlorostannate (mp. 78 °C), described by Parshall in 1972 (Scheme 5.2-1, a)) [1]. In 1987, Knifton reported the ruthenium- and cobalt-catalyzed hydroformylation of internal and terminal alkenes in molten [Bu4P]Br, a salt that falls under the now accepted definition for an ionic liquid (see Scheme 5.2-1, b)) [2]. The first applications of room-temperature ionic liquids in homogeneous transition metal catalysis were described in 1990 by Chauvin et al. and by Wilkes et ak. Wilkes et al. used weekly acidic chloroaluminate melts and studied ethylene polymerization in them with Ziegler-Natta catalysts (Scheme 5.2-1, c)) [3]. Chauvin s group dissolved nickel catalysts in weakly acidic chloroaluminate melts and investigated the resulting ionic catalyst solutions for the dimerization of propene (Scheme 5.2-1, d)) [4]. [Pg.214]

The performance of VASP for alloys and compounds has been illustrated at three examples The calculation of the properties of cobalt dislicide demonstrates that even for a transition-metal compound perfect agreement with all-electron calculations may be achieved at much lower computational effort, and that elastic and dynamic properties may be predicted accurately even for metallic systems with rather long-range interactions. Applications to surface-problems have been described at the example of the. 3C-SiC(100) surface. Surface physics and catalysis will be a. particularly important field for the application of VASP, recent work extends to processes as complex as the adsorption of thiopene molecules on the surface of transition-metal sulfides[55]. Finally, the efficiciency of VASP for studying complex melts has been illustrate for crystalline and molten Zintl-phases of alkali-group V alloys. [Pg.80]

Silver-palladium-manganese brazes possess excellent creep characteristics and have been developed for high-temperature applications involving the use of cobalt or nickel-based alloys, heat-resistant steels, molybdenum and tungsten. Their liquidus temperatures lie in the range 1 100-1 250°C. [Pg.937]

So far, few of the commercially operated diffusion processes have been applied to the lower-melting-point metals. While they are being used to an increasing extent for protection of nickel, cobalt and refractory alloys, the bulk of present-day applications is still concerned with the treatment of ferrous materials. [Pg.396]


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See also in sourсe #XX -- [ Pg.273 ]

See also in sourсe #XX -- [ Pg.326 , Pg.327 ]




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