Molybdenum salts

Lake or pigment dyes form insoluble compounds with aluminum, barium, or chromium on molybdenum salts the precipitates are ground to form pigments used in paint and inks. 

Sodium molybdate (Basic form of components for pigments fertilizers and other molybdenum salts... 

Synonym(s) Chromic acid, lead and molybdenum salt lead chromate, sulphate and molybdate molybdenum-lead chromate molybdenum orange Lead dinitrate nitric acid lead(2+) salt lead (II) nitrate plumbous nitrate Lead(2+) oxide lead monoxide litharge massicot Lead(2+) phosphate Phosphoric acid lead(2+) salt ... 

The baking process has remained much the same until the present day at a stoichiometric ratio of 1 4, phthalic anhydride or phthalic acid reacts with an ammonia releasing compound. The reaction may also start from other suitable materials, such as phthalic acid derivatives, including phthalic acid esters, phthalic acid diamide, or phthalimide. Appropriate ammonia releasing agents include urea and its derivatives, such as biuret, guanidine, and dicyanodiamide. The fact that a certain amount of urea decomposes to form side products makes it necessary to use excess urea. Approximately 0.2 to 0.5, preferably 0.25 equivalents of copper salt should be added for each mole of phthalic anhydride. 0.1 to 0.4 moles of molybdenum salt per mole of phthalic anhydride is sufficient. The reaction temperature is between 200 and 300°C. 

The phthalic anhydride/urea process may also be employed to convert tetra-chloro phthalic anhydride to green copper hexadecachloro phthalocyanine by condensation. In this case, titanium or zirconium dioxides, particularly in the form of hydrated gels, are used instead of the molybdenum salts which are used in the phthalic anhydride process [23]. There is a certain disadvantage to the fact that the products lack brilliance and require additional purification. 

Initially tests were conducted in glass equipment at atmospheric pressure. It was discovered that a more durable catalyst could be made if the Group VI metal oxide were deposited on an alumina support. The best support found for this reaction was alumina, and the first commercial catalyst was made by impregnating a material very similar to activated alumina 1 with a molybdenum salt solution, followed by drying and calcining at a temperature above 1000° F. Interestingly enough, the supported chromia catalyst which showed a marked superiority over the supported molybdena catalyst at atmospheric... 

The specific role and the fate of Mo in the alloy has been investigated [141]. It has been found that Mo is not at all stable but tends to be leached out, which would be the origin of the deactivation observed on cathodic load. The deactivation results in a progressive increase in the Tafel slope, which cannot be reactivated in situ by addition of molybdenum salts. On the other hand, that Mo is leachable can be inferred also from the observation that in situ deposited Co-Mo alloys are quickly dissolved as the current is interrupted [528, 529]. This seems to indicate a provisory activation of the cathode by Mo, which cannot be recovered in a simpley way once decayed [141]. However, this contrasts somewhat with the claim of long term stability and resistance to cell shut-downs for the thermally prepared Ni-Mo coating [5]. The structure of the layer may differ depending on the details of the preparation procedure. 

Molybdenum salts used as catalysts include cobalt molybdate for hydrogen treatment of petroleum stocks for desulfurization, and phospho-molybdates to promote oxidation. Compounds used for dyes are sodium, potassium, and ammonium molybdates. With basic dyes, phosphomolyb-dic acid is employed. The pigment known as molybdenum orange is a mixed crystal of lead chromate and lead molybdate. Sodium molybdate, or molybdic oxide, is added to fertilizers as a beneficial trace element. Zinc and calcium molybdate serve as inhibitory pigments in protective coatings arid paint for metals subjected to a corrosive atmosphere. Compounds used to produce better adherence of enamels are molybdenum trioxide and ammonium, sodium, calcium, barium, and lead molybdates. 

This review deals only with the heterogeneous oxidation of-carbon monoxide by solid materials which show some catalytic activity or a fast surface reaction. It does not include purely stoichiometric reagents used in detection and analysis, such as iodine pentoxide, mercuric oxide, palladium salts activated by molybdenum salts, or liquid-gas systems. A review of such agents has recently been presented elsewhere (11). Furthermore, no attempt has been made to provide complete coverage of the numerous patents in this field, although a number of the more important ones are mentioned. 

SYNS CHROMIC ACID, LEAD and MOLYBDENUM SALT CHROMIC ACID LEAD SALT with LEAD MOLYBDATE C.I. PIGMENT RED 104 LEAD CHROMATE, SULPHATE and MOLYBDATE MOLYBDENUM-LEAD CHROMATE MOLYBDENUM ORANGE... 

Electrochemical method [54] Silicate is determined in sea water by four different electrochemical methods based on the detection of the silicomolybdic complex formed in acidic media by the reaction between silicate and molybdenum salts. The first two methods are based on the addition of molybdate and protons in a seawater sample in an electrochemical cell. A semiautonomous method was developed based on the electrochemical anodic oxidation of molybdenum, the complexation of the oxidation product with silicate and the detection of the complex by cyclic voltammetry. Finally a complete reagent-less method with a precision of 2.6% is described based on the simultaneous formation of the molybdenum salt and protons in a divided electrochemical cell. 

The alkali hexathiocyanates are not isomorphous amongst themselves, but each molybdenum salt is isomor )hous with the corresponding chromium salt (see p. 99) thus ... 

Potassium cacodylate, (CIl3)2As02K.ll20. A very d< lisparingly soluble in alcohol, insoluble in ether." 11 forms a molybdenum salt with molybdie acid, whieh crystallises in ne<"dl< s of composition ... 

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