Molybdenum

Molybdenum is a chemical element; it has symbol Mo and atomic number 42. The name is derived from Ancient Greek μόλυβδος , meaning lead, since its ores were sometimes confused with those of lead. Molybdenum minerals have been known throughout history, but the element was discovered in 1778 by Carl Wilhelm Scheele. The metal was first isolated in 1781 by Peter Jacob Hjelm.
Molybdenum does not occur naturally as a free metal on Earth; in its minerals, it is found only in oxidized states. The free element, a silvery metal with a grey cast, has the sixth-highest melting point of any element. It readily forms hard, stable carbides in alloys, and for this reason most of the world production of the element is used in steel alloys, including high-strength alloys and superalloys.
Most molybdenum compounds have low solubility in water. Heating molybdenum-bearing minerals under oxygen and water affords molybdate ion, which forms quite soluble salts. Industrially, molybdenum compounds are used as pigments and catalysts.
are by far the most common bacterial catalysts for breaking the chemical bond in atmospheric molecular nitrogen in the process of biological nitrogen fixation. At least 50 molybdenum enzymes are now known in bacteria, plants, and animals, although only bacterial and cyanobacterial enzymes are involved in nitrogen fixation. Most nitrogenases contain an iron–molybdenum cofactor FeMoco, which is believed to contain either Mo or Mo. By contrast Mo and Mo are complexed with molybdopterin in all other molybdenum-bearing enzymes. Molybdenum is an essential element for all higher eukaryote organisms, including humans. A species of sponge, Theonella conica, is known for hyperaccumulation of molybdenum.

Characteristics

Physical properties

In its pure form, molybdenum is a silvery-grey metal with a Mohs hardness of 5.5 and a standard atomic weight of 95.95 g/mol. It has a melting point of, sixth highest of the naturally occurring elements; only tantalum, osmium, rhenium, tungsten, and carbon have higher melting points. It has one of the lowest coefficients of thermal expansion among commercially used metals.

Chemical properties

Molybdenum is a transition metal with an electronegativity of 2.16 on the Pauling scale. It does not visibly react with oxygen or water at room temperature, but is attacked by halogens and hydrogen peroxide. Weak oxidation of molybdenum starts at ; bulk oxidation occurs at temperatures above 600 °C, resulting in molybdenum trioxide. Like many heavier transition metals, molybdenum shows little inclination to form a cation in aqueous solution, although the Mo³⁺ cation is known to form under carefully controlled conditions.
Gaseous molybdenum consists of the diatomic species Mo₂. That molecule is a singlet, with two unpaired electrons in bonding orbitals, in addition to 5 conventional bonds. The result is a sextuple bond.

Isotopes

There are 39 known isotopes of molybdenum, ranging in atomic mass from 81 to 119, as well as 13 metastable nuclear isomers. Seven isotopes occur naturally, with atomic masses of 92, 94, 95, 96, 97, 98, and 100. Molybdenum-98 is the most abundant, comprising 24.14% of natural molybdenum, and only molybdenum-100 is unstable; it undergoes double beta decay into ruthenium-100 with half-life 7.07 years.
All the synthetic isotopes of molybdenum decay into isotopes of niobium, technetium, or zirconium. The most stable of them is ⁹³Mo, with a half-life of 4,839 years to electron capture, giving stable niobium.
The most common isotopic molybdenum application involves molybdenum-99, which is a fission product. It is a parent radioisotope to the short-lived gamma-emitting daughter radioisotope technetium-99m, a nuclear isomer used in various imaging applications in medicine.

Redox buffer in the irradiated fuel matrix

Molybdenum behaves as a redox buffer in the spent nuclear fuel matrix. ⁹⁹Mo is one of the most abundant fission product, with a fission yield of 6.1% close to that of xenon. Molybdenum plays a critical role in nuclear fuel chemistry because it affects the fuel's oxygen fugacity. Molybdenum produced by nuclear fission in the fuel matrix inhibits the oxidation of the uranium dioxide.

Compounds

Molybdenum forms chemical compounds in oxidation states −4 and from −2 to +6. Higher oxidation states are more relevant to its terrestrial occurrence and its biological roles, mid-level oxidation states are often associated with metal clusters, and very low oxidation states are typically associated with organomolybdenum compounds. The chemistry of molybdenum and tungsten show strong similarities. The relative rarity of molybdenum, for example, contrasts with the pervasiveness of the chromium compounds. The highest oxidation state is seen in molybdenum oxide, whereas the normal sulfur compound is molybdenum disulfide MoS₂.

Oxidation state	Example
−4
−2
−1
0	Molybdenum hexacarbonyl\|
+1	Cyclopentadienylmolybdenum tricarbonyl\|
+2	Molybdenum chloride\|
+3	Molybdenum bromide\|
+4	Molybdenum disulfide\|
+5	Molybdenum chloride\|
+6	Molybdenum fluoride\|

File:Phosphotungstate-3D-polyhedra.png|thumb|upright|Keggin structure of the phosphomolybdate anion, an example of a polyoxometalate
From the perspective of commerce, the most important compounds are molybdenum disulfide and molybdenum trioxide. The black disulfide is the main mineral. It is roasted in air to give the trioxide:
The trioxide, which is volatile at high temperatures, is the precursor to virtually all other Mo compounds as well as alloys. Molybdenum has several oxidation states, the most stable being +4 and +6.
Molybdenum oxide is soluble in strong alkaline water, forming molybdates. Molybdates are weaker oxidants than chromates. They tend to form structurally complex oxyanions by condensation at lower pH values, such as ⁶⁻ and ⁴⁻. Polymolybdates can incorporate other ions, forming polyoxometalates. The dark-blue phosphorus-containing heteropolymolybdate P³⁻ is used for the spectroscopic detection of phosphorus.
The broad range of oxidation states of molybdenum is reflected in various molybdenum chlorides:

Molybdenum chloride MoCl₂, which exists as the hexamer Mo₆Cl₁₂ and the related dianion ^2-.
Molybdenum chloride MoCl₃, a dark red solid, which converts to the anion trianionic complex ^3-.
Molybdenum chloride MoCl₄, a black solid, which adopts a polymeric structure.
Molybdenum chloride MoCl₅ dark green solid, which adopts a dimeric structure.
Molybdenum chloride MoCl₆ is a black solid, which is monomeric and slowly decomposes to MoCl₅ and Cl₂ at room temperature.

The accessibility of these oxidation states depends quite strongly on the halide counterion: although molybdenum fluoride is stable, molybdenum does not form a stable hexachloride, pentabromide, or tetraiodide.
Like chromium and some other transition metals, molybdenum forms quadruple bonds, such as in Mo₂₄ and ⁴⁻. The Lewis acid properties of the butyrate and perfluorobutyrate dimers, Mo₂₄ and Rh₂ ₄, have been reported.
The oxidation state 0 and lower are possible with carbon monoxide as ligand, such as in molybdenum hexacarbonyl, Mo₆.

History

—the principal ore from which molybdenum is now extracted—was previously known as molybdena. Molybdena was confused with and often used as though it were graphite. Like graphite, molybdenite can be used to blacken a surface or as a solid lubricant. Even when molybdena was distinguishable from graphite, it was still confused with the common lead ore PbS ; the name comes from Ancient Greek μόλυβδος mólybdos, meaning lead..
Although molybdenum was deliberately alloyed with steel in one 14th-century Japanese sword, that art was never employed widely and was later lost. In the West in 1754, Bengt Andersson Qvist examined a sample of molybdenite and determined that it did not contain lead and thus was not galena.
By 1778 Swedish chemist Carl Wilhelm Scheele stated firmly that molybdena was neither galena nor graphite. Instead, Scheele correctly proposed that molybdena was an ore of a distinct new element, and from which it might be isolated. Peter Jacob Hjelm successfully isolated a metal he called molybdaenum using carbon and linseed oil in 1781.
For the next century, molybdenum had no industrial use. It was relatively scarce, the pure metal was difficult to extract, and the necessary techniques of metallurgy were immature. Early molybdenum steel alloys showed great promise of increased hardness, but efforts to manufacture the alloys on a large scale were hampered with inconsistent results, a tendency toward brittleness, and recrystallization. In 1906, William D. Coolidge filed a patent for rendering molybdenum ductile, leading to applications as a heating element for high-temperature furnaces and as a support for tungsten-filament light bulbs; oxide formation and degradation require that molybdenum be physically sealed or held in an inert gas. In 1913, Frank E. Elmore developed a froth flotation process to recover molybdenite from ores; flotation remains the primary isolation process.
During World War I, demand for molybdenum spiked; it was used both in armor plating and as a substitute for tungsten in high-speed steels. Some British tanks were protected by 75 mm manganese steel plating, but this proved to be ineffective. The manganese steel plates were replaced with much lighter molybdenum steel plates allowing for higher speed, greater maneuverability, and better protection. The Germans also used molybdenum-doped steel for heavy artillery, like in the super-heavy howitzer Big Bertha, because traditional steel melts at the temperatures produced by the propellant of the one ton shell. After the war, demand plummeted until metallurgical advances allowed extensive development of peacetime applications. In World War II, molybdenum again saw strategic importance as a substitute for tungsten in steel alloys.