Corrosion molybdenum

Fig. 5.2 Molybdenum corrosion tests in hydrochloric acid (after Bishop, C. R., Corrosion,...

ASTM A 890/A 890M-99(2003) Standard Specification for Castings, Iron-Chromium-Nickel-Molybdenum Corrosion-Resistant, Duplex (Austenitic/Ferritic) for General Application (contains the major duplex grades)... 

ASTM A 890, Standard specification for castings, iron-chromium-nickel-molybdenum corrosion-resistant, duplex (austeniticiferritic) for general application. 

Increased series resistance due to interconnect corrosion has two possible origins degradation of the Mo/ZnO contact (P2 interconnect via) and corrosion of the molybdenum which is exposed to the atmosphere in the P3 scribe-line. Bare molybdenum films on glass corrode rapidly in damp heat and partially form a transparent oxide. Nevertheless, corrosion of the molybdenum in P3 does not seem to contribute significantly to the module degradation until the molybdenum in the scribe has oxidized completely, the interconnect is broken, and the module efficiency is practically zero [54]. It has been reported that molybdenum corrosion occurs faster when the molybdenum film is mechanically stressed [55]. Nevertheless, total breakdown of the interconnect should happen only under unrealistically extreme conditions. 

Hazard Ignites on contact with selenium, iodine, phosphorus, arsenic, antimony, boron, silicon, molybdenum. Corrosive to tissue. 

Molybdic acid anhydride Molybdic anhydride Molybdic oxide Molybdic trioxide Natural molybdite NSC 216191. Source of Mo reagent for analytical chemistry agriculture manufacture of metallic molybdenum corrosion inhibitor ceramic glazes enamels pigments catalyst. Yellow-blue powder mp = 795° bp = 1155° 4.696 soluble in H2O (0.49 g/l), insoluble in organic solvents LDso (rat orl) = 2689 mg/kg, AAA Molybdenum Atomergic Chemetals Cerac Climax Molybdenum Co. 

It is used in certain nickel-based alloys, such as the "Hastelloys(R)" which are heat-resistant and corrosion-resistant to chemical solutions. Molybdenum oxidizes at elevated temperatures. The metal has found recent application as electrodes for electrically heated glass furnaces and foreheaths. The metal is also used in nuclear energy applications and for missile and aircraft parts. Molybdenum is valuable as a catalyst in the refining of petroleum. It has found applications as a filament material in electronic and electrical applications. Molybdenum is an... 

Common alloying elements include nickel to improve low temperature mechanical properties chromium, molybdenum, and vanadium to improve elevated-temperature properties and silicon to improve properties at ordinary temperatures. Low alloy steels ate not used where corrosion is a prime factor and are usually considered separately from stainless steels. 

Molybdenum hexafluoride is classified as a corrosive and poison gas. It is stored and shipped in steel, stainless steel, or Monel cylinders approved by DOT. Electronic and semiconductor industries prefer the cylinders equipped with valves which have Compressed Gas Association (CGA) 330 outlets. 

Chromium is the most effective addition to improve the resistance of steels to corrosion and oxidation at elevated temperatures, and the chromium—molybdenum steels are an important class of alloys for use in steam (qv) power plants, petroleum (qv) refineries, and chemical-process equipment. The chromium content in these steels varies from 0.5 to 10%. As a group, the low carbon chromium—molybdenum steels have similar creep—mpture strengths, regardless of the chromium content, but corrosion and oxidation resistance increase progressively with chromium content. 

AISI 321 and 347 are stainless steels that contain titanium and niobium iu order to stabilize the carbides (qv). These metals prevent iatergranular precipitation of carbides during service above 480°C, which can otherwise render the stainless steels susceptible to iatergranular corrosion. Grades such as AISI 316 and 317 contain 2—4% of molybdenum, which iacreases their creep—mpture strength appreciably. In the AISI 200 series, chromium—manganese austenitic stainless steels the nickel content is reduced iu comparison to the AISI 300 series. 

Tantalum and 2kconium exhibit the highest corrosion resistance to HCl. However, the corrosion resistance of 2ironium is severely impaHed by the presence of ferric or cupric chlorides. Tantalum—molybdenum alloys containing more than 50% tantalum are reported to have exceUent corrosion resistance (see Molybdenumand molybdenum alloys) (69). Pure molybdenum and tungsten are corrosion resistant in hydrochloric acid at room temperature and also in 10% acid at 100°C but not in boiling 20% acid. 

Moist iodine vapor rapidly corrodes metals, including most stainless steels. The initial process is the formation of corrosion centers where small amounts of metal iodide are formed which deHquesce, and the corrosion then takes place electrochemically (41,42). Only titanium and molybdenum steels are unattacked by iodine (42,43). The corrosion of molten iodine has also been studied. 

The only metals having good or excellent resistance to corrosion by amalgamation with mercury are vanadium, iron, niobium, molybdenum, cesium, tantalum, and tungsten (8). The diffusion rates of some metals in mercury are given in Table 5. 

Molybdenum improves the corrosion resistance of stainless steels that are alloyed with 17—29% chromium. The addition of 1—4% molybdenum results in high resistance to pitting in corrosive environments, such as those found in pulp (qv) and paper (qv) processing (33), as weU as in food preparation, petrochemical, and poUution control systems. 

Coatings, Paints, and Pigments. Various slightly soluble molybdates, such as those of zinc, calcium, and strontium, provide long-term corrosion control as undercoatings on ferrous metals (90—92). The mechanism of action presumably involves the slow release of molybdate ion, which forms an insoluble ferric molybdate protective layer. This layer is insoluble in neutral or basic solution. A primary impetus for the use of molybdenum, generally in place of chromium, is the lower toxicity of the molybdenum compound. 

Another set of nickel aHoys, which have a high chromium content, a moderate molybdenum content, and some copper, are the ILLIUM aHoys. These cast aHoys are wear and erosion resistant and highly resistant to corrosion by acids and alkaHes under both oxidizing and reducing conditions. 

Vitahium FHS ahoy is a cobalt—chromium—molybdenum ahoy having a high modulus of elasticity. This ahoy is also a preferred material. When combiaed with a properly designed stem, the properties of this ahoy provide protection for the cement mantle by decreasing proximal cement stress. This ahoy also exhibits high yields and tensile strength, is corrosion resistant, and biocompatible. Composites used ia orthopedics include carbon—carbon, carbon—epoxy, hydroxyapatite, ceramics, etc. 

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