| Identification | More | [Name]
Molybdenum | [CAS]
7439-98-7 | [Synonyms]
tsm1
mchvl
MO007902
MO007906
MO000450
MO000090
MO005350
MO005150
MO005105
MO008710
MO007052
MO000375
MO005153
MO000200
MO007300
MO000220
MO000280
MO000360
MO005220
MO000203
MO006100
MO000392
MO005320
MO005825
MO005160
MO000385
MO005155
MO000330
MO005140
MO005120
MO000150
MO005110
MO000140
MO000201
MO000110
MO007412
MO005135
MO007908
MO005125
MO007063
MO007302
MO007920
MO007903
MO000383
MO000410
MO004850
MO007901
MO000170
MO007401
MO004500
MO000310
MO007945
MO000370
MO000350
MO000130
MO000215
MO005225
MO007905
MO007413
MO000485
MO007051
MO000205
MO007375
MO007900
MO005152
MO007926
MO000420
MO005165
MO007950
MO007910
MO005122
MO007904
MO005215
MO000380
MO000080
MO000120
MO005130
MO008720
MO005340
MO005121
MO007350
MO005142
MO007200
MO000270
MO000240
MO000211
MO000230
MO000390
MO000100
MO000374
MO007931
MO000250
MO007922
MO000210
MOLYBDATE
Molybdaen
Molybdium
NSC 600660
NSC 600661
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NSC 603570
NSC 603571
NSC 603572
MOLYBDENUM
TRIPLE SUG
MOLYBDENIUM
CCA COLIFORMS
Molybdenum rod
molybdenum atom
Molybdenum slug
Molybdenum wire
molybdenum fume
Nano-molybdenum
Molybdenum foil
Molybdium metal
MOLYBDENUM METAL
Molybdenum, lump
mclybdenum powder
Molybdenum powder
MOLYBDENUM PELLET
MOLYBDENUM 99.99%
Molybdenum sheets
Molybdenium powder
Molybdenum element
MOLYBDENUM STANDARD
Molybdenum crucible
molybdeneelementaire
MOLYBDENUM FOIL, 3N5
MOLYBDENUM(METALLIC)
MolybdenumwireNmmdia
Molybdenum (O, N, C)
MolybdenumpelletsNxmm
MolybdenumpowderNmesh
Molybdenum nanopowder
Molybdenum foil50x50mm
Nano Molybdenum Powder
MOLYBDENUM AA STANDARD
Molybdenumfoil(99.95%)
MOLYBDENUM METAL SHEET
6.4 MM DIA. (~3.6G/CM)
Molybdenum powder (Mo)
Molybdenum sheets (Mo)
MolybdenumpowderNmicron
Molybdenum rod (99.95%)
Molybdenum, Hot Pressed
Molybdenum wire (99.9%)
Molybdenum powder, 99+%
Molybdenumpowder(99.9%)
MOLYBDENUM ICP STANDARD
Molybdenum plate50x50mm
INDIUM 1,000PPM FOR ICP
Molybdenum gauze75x75mm
Molybdenum plate50x200mm
Molybdenum foil300x600mm
Molybdenum foil300x300mm
Molybdenum foil150x300mm
Molybdenum foil150x150mm
Molybdenum foil100x100mm
Molybdenum foil200x200mm
Molybdenumpowder(99.95%)
Molybdenum wire (99.97%)
MolybdenumrodNmmdiacagcm
Molybdenum foil100x150mm
Molybdenum, Mo 1000μg/mL
Molybdenum sheet (99.95%)
Molybdenum gauze150x150mm
Molybdenum foil300x1200mm
Molybdenum gauze300x300mm
MOLYBDENUM , POWDER, 1-3MM
MOLYBDENUM WIRE: 99.9%, 3N
MolybdenuM, powder, -20 μM
Molybdenum pellets (99.7%)
40914 MOLYBDENUM (O N C)
77878 MOLYBDENUM (O N C)
MOLYBDENUM ROD: 99.95%, 3N5
Molybdenum, Powder 100 Mesh
MOLYBDENUM ICP/DCP STANDARD
MOLYBDENUM POWDER 99+ 100 G
Molybdenum powder (Mo) 2 μm
MOLYBDENUM STANDARD SOLUTION
MOLYBDENUM POWDER: 99.9%, 3N
MOLYBDENUM WIRE: 99.97%, 3N7
Molybdenum, powder, 200 mesh
Molybdenum, pellets, 1/4x1/2
Molybdenum, pellets, 1/4x1/4
Molybdenum, pellets, 1/8x1/4
Molybdenum, pellets, 1/8x1/8
Molybdenum solution 1000 ppm
MolybdenumsheetNmmthickcagxmm
Molybdenum, nanopowder, 99.8%
MOLYBDENUM POWDER EXTRA PURE
MOLYBDENUM SHEET: 99.95%, 3N5
Molybdenum powder , ball-like
Molybdenum powder,sphere (Mo)
Molybdenum ISO 9001:2015 REACH
MOLYBDENUM POWDER: 99.95%, 3N5
MOLYBDENUM PELLETS: 99.7%, 2N7
Molybdenum solution 10 000 ppm
Molybdenum, pellets, 6 x 16 mm
Molybdenum Wire 2.0 mm diameter
Molybdenum,99.98%,powder, -20 μm
Molybdenum powder, <40 μm, 99.9%
Molybdenum rod, dia 3 mm, 99.95%
MOLYBDENUM, AAS STANDARD SOLUTION
Molybdenum, Pellets, 6X16mm 99.7%
MOLYBDENUM SINGLE ELEMENT STANDARD
Molybdenum, powder, -20 μm, 99.98%
MOLYBDENUM: 99.97%, WIRE, 1MM DIA.
Molybdenum, Powder 100 Mesh 99.95%
Molybdenum rod, 5mm (0.2 in.) dia.
Molybdenum chunks, 1-10 mm, 99.95%
Molybdenum wire, dia 0.5mm, 99.95%
Molybdenum wire, dia 1.0mm, 99.95%
MolybdenuM wire,2.0MM dia.annealed
Molybdenum powder , ball-like (Mo)
Molybdenum wire, dia 0.013mm, 99.8%
Molybdenum powder, -250 mesh, 99.9%
MolybdenuM slug,6MM dia×6MM length.
MOLYBDENUM METALLO-ORGANIC STANDARD
MOLYBDENUM PLASMA EMISSION STANDARD
MOLYBDENUM, PLASMA STANDARD SOLUTION
Molybdenum, powder, 200 mesh, 99.99%
MOLYBDENUM: 99.95%, POWDER, 6 MICRON
MOLYBDENUM: 99.97%, WIRE, 0.5MM DIA.
MOLYBDENUM ROD 5.0MM DIAM. 99.95%
MOLYBDENUM, 99.99%, POWDER, 200 MESH
Molybdenum foil, 0.2 mm thick, 99.9%
Molybdenum powder, -325 mesh, 99.9%+
Molybdenum powder, -325 mesh, 99.997%
Molybdenum powder, -22 mesh, 99.9975%
Molybdenum powder, -325 mesh, 99.999%
MOLYBDENUM ATOMIC ABSORPTION STANDARD
MOLYBDENUM, FOIL, 0.1MM THICK, 99.9+%
MOLYBDENUM POWDER <10 MICRON 99.95%
MOLYBDENUM, WIRE, 1.0MM DIAM., 99.95%
MOLYBDENUM, WIRE, 0.5MM DIAM., 99.95%
MOLYBDENUM, FOIL, 0.5MM THICK, 99.9+%
MOLYBDENUM, FOIL, 1.0MM THICK, 99.9+%
MOLYBDENUM AA SINGLE ELEMENT STANDARD
MOLYBDATE ION CHROMATOGRAPHY STANDARD
MOLYBDENUM: 99.95%, POWDER, 4-8 MICRON
MOLYBDENUM FOIL 0.05MM THICK 99.9+%
MOLYBDENUM, FOIL, 0.25MM THICK, 99.9+%
MOLYBDENUM, WIRE, 0.25MM DIAM., 99.97%
Molybdenum foil, 0.005 mm thick, 99.9%
MolybdenuM standard for water analysis
Molybdenum foil, 1.0mm (0.04 in.) thick
Molybdenum plate, 15 x 15 x 200 mm, 99%
Molybdenum nanopowder, APS 40 nm, 99.9%
MOLYBDENUM, POWDER, <10 MICRON, 99.99+%
MOLYBDENUM, FOIL, 0.025MM THICK, 99.9+%
MOLYBDENUM ATOMIC SPECTROSCOPY STANDARD
MOLYBDENUM, OIL BASED STANDARD SOLUTION
Molybdenum foil, 0.5mm (0.02 in.) thick
MOLYBDENUM METAL POWDER 3.5-4.5M: 99.95%
Molybdenum (insoluble compounds) (as Mo)
ANTIBIOTIC MEDIUM A 200ML IN 250ML BOTTL
MOLYBDENUM STANDARD SOLUTION TRACEABLE T
MOLYBDENUM ICP STANDARD TRACEABLE TO SRM
Molybdenum Nanopowder, APS 100 nm, 99.9%
Molybdenum Nanopowder, APS 130 nm, 99.9%
Molybdenum foil, 0.05mm (0.002 in.) thick
Molybdenum plate, 2.5mm (0.098 in.) thick
MOLYBDENUM METAL POWDER: 99.95%, 2.0-3.0M
MOLYBDENUM SINGLE ELEMENT PLASMA STANDARD
Molybdenum plate, 4.76mm (0.188 in.) thick
Molybdenum plate, 12.5mm (0.492 in.) thick
MolybdenuM sputtering target, 76MMx4MMthick
MOLYBDENUM AA/ICP CALIBRATION/CHECK STANDARD
Molybdenum10,000mg/L±2%in10%HCl100ml(MoMetal)
Molybdenum, irregular particles, <30 mm, 99.8%
Molybdenum AAS standard solution, Mo 1000μg/mL
Molybdenum foil, 0.5 mm (0.02in) thick, 99.95%
Molybdenum wire (99.97%) (2.0mm dia., 32.1g/m)
MOLYBDENUM ATOMIC ABSORPTION STANDARD SOLUTION
Molybdenum, soluble compounds (respirable dust)
Molybdenum wire, 0.203mm (0.008 in.) dia., Hard
Molybdenum wire, 0.025mm (0.001 in.) dia., Hard
Molybdenum foil, 0.127mm (0.005 in.) thick, Hard
Molybdenum, plasma standard solution, Mo 10μg/mL
Molybdenum rod, dia x length 10 mm x 100 mm, 99%
MOLYBDENUM PLASMA EMISSION SPECTROSCOPY STANDARD
Molybdenum rod, 3.17mm (0.125 in.) dia., Annealed
Molybdenum wire, 0.013mm (0.00052 in.) dia., Hard
Molybdenum powder, (-140 mesh / +325 mesh), 99.5% | [EINECS(EC#)]
231-107-2 | [Molecular Formula]
Mo | [MDL Number]
MFCD00003465 | [Molecular Weight]
95.94 | [MOL File]
7439-98-7.mol |
| Chemical Properties | Back Directory | [Description]
Molybdenum is an essential trace mineral associated with several enzyme systems required for the normal body functions. Mine workers have developed symptoms of molybdenosis. The significantly expanding or softening property of the material makes it useful in applications that involve intense heat, including the manufacture of aircraft parts, electrical contacts, industrial motors, and filaments. | [Definition]
Metallic element of atomicnumber 42, group VIB of the periodic table, aw95.94, valences = 2, 3, 4, 5, 6. Seven stable isotopes. | [Appearance]
Molybdenum is a silvery-white metal or dark
gray or black powder with a metallic luster. | [Melting point ]
2617 °C (lit.) | [Boiling point ]
4612 °C (lit.) | [density ]
10.3 g/mL at 25 °C(lit.)
| [refractive index ]
2.81 (740 nm) | [Fp ]
-23 °C | [storage temp. ]
Flammables area | [solubility ]
H2O: soluble
| [form ]
wire
| [color ]
Gray | [Specific Gravity]
10.2 | [Stability:]
Stable. Powder is flammable. | [Resistivity]
5.0 μΩ-cm, 20°C | [Water Solubility ]
Insoluble inwater. Soluble innitric acid andsulfuric acid. Slightly soluble inhydrochloric acid. | [Sensitive ]
Air Sensitive | [Merck ]
13,6257 | [Exposure limits]
ACGIH: TWA 10 mg/m3; TWA 3 mg/m3
NIOSH: IDLH 5000 mg/m3 | [CAS DataBase Reference]
7439-98-7(CAS DataBase Reference) | [EPA Substance Registry System]
Molybdenum (7439-98-7) |
| Safety Data | Back Directory | [Hazard Codes ]
F,Xi,N,Xn | [Risk Statements ]
R36/38:Irritating to eyes and skin .
R11:Highly Flammable.
R67:Vapors may cause drowsiness and dizziness.
R65:Harmful: May cause lung damage if swallowed.
R62:Possible risk of impaired fertility.
R51/53:Toxic to aquatic organisms, may cause long-term adverse effects in the aquatic environment .
R48/20:Harmful: danger of serious damage to health by prolonged exposure through inhalation .
R38:Irritating to the skin. | [Safety Statements ]
S26:In case of contact with eyes, rinse immediately with plenty of water and seek medical advice .
S36/37/39:Wear suitable protective clothing, gloves and eye/face protection .
S16:Keep away from sources of ignition-No smoking .
S9:Keep container in a well-ventilated place .
S62:If swallowed, do not induce vomiting: seek medical advice immediately and show this container or label .
S61:Avoid release to the environment. Refer to special instructions safety data sheet .
S36/37:Wear suitable protective clothing and gloves . | [RIDADR ]
UN 3264 8/PG 3
| [WGK Germany ]
3
| [RTECS ]
QA4680000
| [TSCA ]
Yes | [HazardClass ]
4.1 | [PackingGroup ]
III | [HS Code ]
81029600 | [Safety Profile]
Poison by intratracheal
route. Mutation data reported. An
experimental teratogen. Experimental
reproductive effects. Flammable or
explosive in the form of dust when exposed
to heat or flame. Violent reaction with oxidants (e.g., bromine trifluoride, bromine
pentafluoride. chlorine trifluoride, potassium
perchlorate, nitryl fluoride, fluorine, iodine
pentafluoride, sodium peroxide, lead
dioxide). When heated to decomposition it
emits toxic fumes of Mo. | [Hazardous Substances Data]
7439-98-7(Hazardous Substances Data) | [IDLA]
5,000 mg Mo/m3 |
| Hazard Information | Back Directory | [General Description]
MOLYBDENUM(7439-98-7), a chemical element, is a hard, high-melting (refractory) high-density dark gray metal or black powder. Insoluble in water. Used to make structural alloys; used as a catalyst. MOLYBDENUM(7439-98-7) dust and fumes can irritate the eyes and respiratory tract. | [Reactivity Profile]
MOLYBDENUM is a reducing agent. In dust or powder form, MOLYBDENUM may present a fire or explosion hazard under favoring conditions of particle size, dispersion and ignition. Bulk molybdenum (rod, coil, sheet, etc.) is less reactive than dust or powder. Insoluble in hydrochloric acid or hydrofluoric acid solutions and in ammonia and sodium hydroxide solutions. Insoluble in dilute sulfuric acid solutions but soluble in concentrated sulfuric acid. Soluble in concentrated nitric acid. Incompatible with strong oxidizing agents such as bromine trifluoride, bromine pentafluoride, chlorine trifluoride, potassium perchlorate, nitryl fluoride, fluorine, iodine pentafluoride, sodium peroxide, lead dioxide. | [Hazard]
Flammable in form of dust or powder.Lower respiratory tract irritant. Questionable car-cinogen. | [Potential Exposure]
Most of the molybdenum produced is
used in alloys: steel, stainless steel; tool steel; case iron;
steel mill rolls; manganese, nickel, chromium, and tungsten.
The metal is used in electronic parts (contacts, spark
plugs, X-ray tubes, filaments, screens, and grids for radios);
induction heating elements; electrodes for glass melting;
and metal spraying applications. Molybdenum compounds
are utilized as lubricants; as pigments for printing inks; lacquers,
paints, for coloring rubber animal fibers, leather, and
as a mordant; as catalysts for hydrogenation cracking;
alkylation, and reforming in the petroleum industry; in
Fischer Tropsch synthesis; in ammonia production; and in
various oxidation-reduction and organic cracking reactions;
as a coating for quartz glass; in vitreous enamels to increase adherence to steel; in fertilizers, particularly for
legumes; in electroplating to form protective coatings; and
in the production of tungsten. Hazardous exposures may
occur during high-temperature treatment in the fabrication
and production of molybdenum products, spraying applications;
or through loss of catalyst. MoO3 sublimes above
800℃. | [First aid]
If this chemical gets into the eyes, remove any
contact lenses at once and irrigate immediately for at least
15 minutes, occasionally lifting upper and lower lids. Seek
medical attention immediately. If this chemical contacts the
skin, remove contaminated clothing and wash immediately
with soap and water. Seek medical attention immediately.
If this chemical has been inhaled, remove from exposure,
begin rescue breathing (using universal precautions, including
resuscitation mask) if breathing has stopped and CPR if
heart action has stopped. Transfer promptly to a medical facility. When this chemical has been swallowed, get medical
attention. Give large quantities of water and induce
vomiting. Do not make an unconscious person vomit. | [Shipping]
UN3089 Metal powders, flammable, n.o.s.,
Hazard Class: 4.1; Labels: 4.1-Flammable solid. | [Incompatibilities]
Metallic Mo is a combustible solid in
form of dust or powder and is potentially explosive. Dust
or powder may form explosive mixture with air. Soluble
compounds: alkali metals; sodium, potassium, molten
magnesium. Insoluble compounds: Violent reaction with
oxidizers, nitric acid; sulfuric acid. Forms explosive mixture
with potassium nitrate. Incompatible with oxidizers
(chlorates, nitrates, peroxides, permanganates, perchlorates,
chlorine, bromine, fluorine, etc.); contact may cause fires
or explosions. Keep away from alkaline materials, strong
bases, strong acids, oxoacids, epoxides. | [Chemical Properties]
Molybdenum is a silvery-white metal or dark
gray or black powder with a metallic luster. | [Waste Disposal]
Recovery is indicated whenever
possible. Processes for recovery of Molybdenum from
scrap, flue dusts, spent catalysts and other industrial wastes
have been developed. | [Isotopes]
There are 36 isotopes of molybdenum, ranging in atomic weights from Mo-83to Mo-115. Of the seven isotopes considered stable, one (Mo-100) is radioactive and isconsidered stable because it has such a long half-life (0.95×10+19 years). The proportionsof the seven stable isotopes contributing to molybdenum’s natural existence onEarth are as follows: Mo-92 = 14.84%, Mo-94 = 9.25%, Mo-95 = 15.92%, Mo-96 =16.68%, Mo-97 = 9.55%, Mo-98 = 24.13%, and Mo-100 = 9.63%. | [Origin of Name]
Molybdenum is derived from the Greek word molybdos, meaning lead.
At one time, the mineral molybdaena (later called molybdenite) was believed to be a
variety of lead ore. | [Occurrence]
Molybdenum is the 54th most abundant element on Earth. It is relatively rare and is foundin just 126 ppm in the Earth’s crust. Its major ore is molybdenite (MoS2), which is mined inColorado in the United States and is found too in Canada, Chile, China, England, Norway,Sweden, Mexico, and Australia. Moldybdenum is also found in two less important ores: wulfenite(PbMoO4) and powellite ([Ca(MoW)O4]. These ores are usually found in the same sitesalong with tin and tungsten ores.
Molybdenite ore is very similar to graphite, and they have been mistaken for each otherin the past. | [Characteristics]
Given that molybdenum is located between chromium and tungsten in group 6, it chemicallyresembles a cross between these two partner elements. The three related elements donot occur as free elements in nature, but rather are found in minerals and ores. Their metal(elemental) radius size increases from chromium = 44 to molybdenum = 59 to tungsten = 60,which is related to their electronegativity and results in their using electrons in shells inside theouter shell during metallic bonding. This is a major characteristic of the transition of elementsfrom metals to nonmetals.
Molybdenum oxidizes at high temperatures but not at room temperatures. It is insolublein acids and hydroxides at room temperatures. At room temperatures, all three metals(chromium, molybdenum, and tungsten) resist atmospheric corrosion, which is one reasonchromium is used to plate other metals. They also resist attacks from acids and strong alkalis,with the exception of chromium, which, unless in very pure form, will dissolve in hydrochloricacid (HCl). | [History]
Peter Jacob Hjelm (1746–1813) is given credit for discovering molybdenum in 1781despite the fact that his paper was not published until 1890. He followed the advice of CarlWilhelm Scheele (1742–1786), who isolated and identified molybdenum, but incorrectlythought it was an element related to lead.
Although some reference works do give Scheele credit, most do not credit him for thediscovery of either molybdenum or the other elements he “discovered,” such as oxygen andmanganese.
Scheele did not receive credit for discovering oxygen two years before Joseph Priestley(1733–1804) announced his discovery and was given the credit. Scheele’s publisher wasnegligent in getting his work published in time. (There is a lesson in this story for all youngscientists—keep completed and accurate records of all your lab work and observations, andwhen you are sure of your experimental results, make sure to publish.)
The name “molybdenum” is derived from the Greek word for lead, molybdos, which standsfor any black minerals that historically could be used for writing. This also explains why theGreek word plumbago or “black lead” was used for graphite. | [Uses]
In the form of ferromolybdenum for manufg special steels for tools, boiler plate, rifle barrels, propeller shafts; electrical contacts, spark plugs, x-ray tubes, filaments, screens and grids for radio tubes; in the production of tungsten; glass-to-metal seals; nonferrous alloys; in colloidal form as lubricant additive. | [Uses]
Molybdenum is largely used in steel industry.Its compounds are widely used incoloring agents, solid lubricants and ascatalysts. Molybdenum is an essential traceelement and a component of xanthine oxidase.This enzyme catalyzes the formationof urate. Molybdenum cofactor (Moco)-deficiencyis a lethal autosomal recessive disease.Moco-deficiency in humans can causeneurological damage, seizures and variousbrain dysmorphisms.
The sources of molybdenum include beans,dark green leafy vegetables, grains and hardtap water. Deficiencies of molybdenum arealmost unknown in human.
| [Uses]
The high melting point of molybdenum is the major determinant of how it is used. Its chiefuse is as an alloy in the manufacture of engines of automobiles. “Moly-steel” contains up to8% molybdenum and can withstand high pressures and the relatively rapid changes of enginetemperatures (e.g. cold engine to hot and back again without the metal warping and with theability to withstand excessive expansion and contraction).
Its high melting point also makes it useful for metal electrodes in glassmaking furnaces.Molybdenum’s high resistance to electricity makes it useful in high-temperature filament wiresand in the construction of parts for missiles, spacecrafts, and nuclear power generators.
Molybdenum is also used as a catalyst in petroleum refining, as a pigment for paints andprinter’s ink, and as a high-temperature lubricant (molybdenum disulphide-MoS2) for use byspacecraft and high-performance automobiles.
In hospitals, radioisotope Mo-99, which decays into technetium-99, is given internally tocancer patients as a “radioactive cocktail.” Radioactive Tc-99 is absorbed by tissues of cancerpatients, and then x-ray-like radiation is used to produce pictures of the body’s internal organs. | [Production Methods]
Molybdenum (Mo) is a dark gray or a black powder with a metallic luster and a chemical element of the second transition series. The name is derived from the Greek molybdos, meaning“lead.”In1778,CarlScheeleofSwedenrecognized molybdenite as a distinct ore of a new element, and in 1781 Hjelm prepared an impure form of the metal. The ?rst molybdenum mine, Knaben Gruver mine in southern Norway, was opened in 1885 and remained open until 1973. Today, the principal molybdenum mines are found in the United States, Chile, and China. Mined ore is crushed in ball or rod mills, and metallic minerals are separated from gangue by ?otation. The pure metal is prepared by the reduction of puri?ed molybdic trioxide or ammonium molybdate (AM) with hydrogen. When Mo is a by-product of copper mining, a concentrate ofcopperandmolybdenumis?rstproduced,andthetwoores are later separated by differential ?otation. MoS2 concentrates contain more than 85% MoS2 and roasted MoO3 typically contains a minimum of 57% Mo and less than 0.1% S. | [Health Hazard]
The toxicity of molybdenum in humans isconsidered to be low. Gout-like symptoms,hyperuricaemia and pneumoconiosis havebeen associated with excessive exposures.Selden et al. (2005) have reported a case ofhyperuricaemia and gouty arthritis in a youngman from occupational exposure to molybdenum.Momcilovic (1999) has cited a caseof acute clinical poisoning resulting from thedietary intake of molybdenum supplement ina male patient. A cumulative dose of 13.5 mgMo over a period of 18 days was attributed tocause acute psychosis with visual and auditoryhallucination and a series of petit malseizures. The symptoms decreased severalhours after the start of chelation therapy withcalcium ethylene diamine tetraacetic acid.However, 1 year after such Mo poisoning thepatient was diagnosed toxic encephalopathywith learning disability, depression, and posttraumaticdisorder. Spectral emission computertomography demonstrated evidence offrontal cortical damage of the brain.
Vyskocil and Viau (1999) assessed molybdenumtoxicity in humans and calculated the‘tolerable daily intake’ (TDI), ‘no observedadverse effect level’ (NOAEL) and the ‘lowestobserved adverse effect level’ (LOAEL)for molybdenum intake. The authors havecalculated a TDI of 0.009 mg Mo/kg/dayand a NOAEL and LOAEL of 0.9 and1.6 mg Mo/kg/day respectively. Their toxicologicalrisk analysis was based on animaldata.
Molybdenum toxicity has been found tobe associated with copper deficiency in thebody.
Thus, any copper deficiency arising eitherfrom inadequate dietary intake or from somedysfunction in copper metabolism that woulddeplete its level may contribute to greaterrisk of molybdenum toxicity in humans. | [Flammability and Explosibility]
Notclassified | [Agricultural Uses]
Molybdenum (Mo) is a plant micronutrient, absorbed by
the plant roots only in the form of molybdate ion MoO42-
Molybdenum, is a vital component of the enzyme,
nitrate reductase (a soluble molybdoflavoprotein) in
Molybdenum is present in the chloroplasts of leaves.
It is also a structural component of nitrogenase which
plays an active role in nitrogen fixation by Rhiwbium,
Azotobucter and some algae and actinomycetes.
Molybdenum is also involved in the absorption and
translocation of iron in plants.
Molybdenum is present in soils in extremely small
quantities (about 2 ppm or less) which is adequate for plants. Its availability increases as the soil pH increases
when the conversion of molybdenum oxide to molybdate
is favored.
The presence of aluminum, iron and titanium in soil
increases the absorption of molybdenum. Nitrate
nitrogen encourages molybdenum uptake, while
ammoniacal nitrogen reduces it. A heavy application of
phosphatic fertilizers increases the uptake of
molybdenum while that of sulphates has the reverse
effect. The addition of lime increases the availability of
molybdenum. A dose of concentrated soluble manganese
and/or copper reduces molybdate absorption by plants.
When the molybdenum content of plants is less than
0.2 ppm, molybdenum deficiency occurs. The
deficiency is determined by the ammonium oxalate
extraction procedure. Acidic soils, fibrous peat soils and
acidic sandy soils are generally molybdenum deficient.
Molybdenum concentration is high at the soil surface, and
decreases with depth; the deficiency is severe under dry
soil conditions, probably owing to reduced diffusion or
mass flow.
Molybdenum deficiency resembles nitrogen
deficiency in legumes, because of the role molybdenum
plays in nitrogen fixation. The deficiency causes stunting
and yellowing of plants. In legume crops, the deficiency
manifests itself by marginal scorching, curling and
crinkling of leaves, the first symptom being
an interveinal chlorosis followed by the plant turning pale
yellow and becoming stunted.
Mo deficiency, manifested in cauliflower, is known as
whiptail and that in cashew, the yellow leaf spot. The deficiency is most common in acidic
sandy soils because of the leaching losses. Molybdenum
availability is low in soils with high metal oxides.
Cauliflower, Brussels sprouts, broccoli and citrus fruits
are sensitive to low molybdate levels. Cotton,
leafy vegetables, corn, tomato and sweet potato are
moderately sensitive to lower molybdate levels.
Molybdenum deficiency also causes nitrate
accumulation, thereby lowering the activity of ascorbic
acid oxidase, known for activating enzymes, namely,
nitrate reductase and xanthine oxidase.
Molybdenum deficiency can easily be corrected by
adding 40 to 400g Mo/ha to the soil. It can also be
corrected by a foliar spray of sodium molybdate or
molybdic acid, or by coating seeds with sodium molybdate before planting. Even a 0.03% foliar spray on
cashews can correct the deficiency. Soil is limed to
increase plant uptake of molybdenum.
A trace of molybdenum as impurity in
superphosphate is often adequate for plant growth. A
material carrying at least 38% molybdenum, such as
sodium molybdate, is employed to coat the seed, about 17
g/ha of which is used for legumes on molybdenumdeficient
soils. Such seed treatment is the most practical
way for augmenting the molybdenum content of the soil.
Ammonium molybdate is recommended for potato at
the rate of about 1 kg/ha for soil application, 0.5 kg in
lo00 liters of water for sprays and 200 g for soaking seed
tubers. A disease, called pencil point, in coconut can be
cured with a 0.25 g/l of ammonium molybdate as a
component of the fertilizer mixture.
Many fertilizers contain molybdenum. The common
ones are ammonium molybdate (54%), sodium
molybdate (39%) and molybdenum trioxide (66%) - the figures in brackets indicating the molybdenum
percentage. Among these, only ammonium molybdate is
recognized under the Fertilizer Control Order (FCO) in
some countries (like India), although sodium molybdate
is the most commonly recommended molybdenum
carrier. Molybdenum is mixed with NPK fertilizer and
then applied. It was demonstrated in Australia that
soaking seeds in sodium molybdate solution before
sowing was as effective as applying molybdenum in the
fertilizer. In the United States, the seeds are often coated
with sodium molybdate.
Molybdenum toxicity is associated with vein
clearing, necrosis, and golden yellow dissolution in the
middle of the lamina in plants because of the formation of
molybdeocatechol complex. Excess of molybdenum is
toxic to animals feeding on forage rich in molybdenum.
Molybdenosis, is a cattle disease, caused by a copper and
molybdenum imbalance in the diet, with the molybdenum
content exceeding 5 ppm. Molybdenum toxicity
provokes stunted growth and bone deformation in
animals. This disease is also known as 'teart' in England
and 'peat scow' in New Zealand. Injecting copper or
adding copper fertilizer to the grazing areas can correct
the imbalance.
As already mentioned, soils generally contain very
low quantities of molybdenum. In most Indian soils
(other than acidic soils), for instance, the total available
molybdenum ranges from traces to a fraction of 1 ppm,
and even with this minute quantity the soil exhibits no
molybdenum deficiency.
| [Industrial uses]
Molybdenum (Mo) is a silvery-white metal, occurring chiefly in the mineral molybdenite but also obtained as a by-product from copper ores. It is ductile, softer than tungsten, and is readily worked or drawn into very fine wire.
Its major use is in alloy steels, for example, as tool steels ( 10% molybdenum), stainless steel, and armor plate. Up to 3% molybdenum is added to cast iron to increase strength. Up to 30% molybdenum may be added to iron-, cobalt-, and nickel-base alloys designed for severe heat- and corrosion-resistant applications. It may be used in filaments for lightbulbs, and it has many applications in electronic circuitry.
Molybdenum forms mirrors and films on glass when it is produced by gas-phase reduction or decomposition of volatile molybdenum compounds in glass tubes. Molybdenum trioxide (MoO3) dissolves in glass, allowing strong binding of molten glass with preoxidized metal surfaces. Annealing is very effective, with little or no difference in thermal expansion at the metal glass interface. Molybdenum found early use in filaments for electric lightbulbs and later in the construction of electronic devices (for example, in vacuum tubes, contacts, electrodes, and transistors). | [Carcinogenicity]
Guinea pigs exposed to molybdenum trioxide
dust at a concentration of 200mg molybdenum/
m3 for 1 hour daily for 5 days developed
nasal irritation, diarrhea, weight loss, and incoordination.
3 In 2-year inhalation studies at concentrations
of up to 100mg/m3 molybdenum
trioxide there was no evidence of carcinogenic
activity in female rats, but there was equivocal
evidence in males based on a marginally significant
positive trend of alveolar/bronchiolar
adenoma or carcinoma (combined). There was
some evidence of carcinogenic activity in mice
based on increased incidences of alveolar/bronchiolar
adenoma and carcinomas (combined).4
Other exposure-related effects in exposed
animals included alveolar inflammation, squamous
metaplasia of the epiglottis and hyaline
degeneration of the respiratory and olfactory
epithelium. Molybdenum trioxide was not
mutagenic in bacterial assays, nor did it induce
sister chromatid exchanges or chromosomal
aberrations in vitro.
| [Environmental Fate]
Molybdenum is a silvery-white transition metal in Group 6
between chromium and tungsten on the periodic table. It is
mined as a principal ore, and is also recovered as a byproduct of
copper and tungsten mining. Molybdenum does not react with
oxygen or water at room temperature, and the bulk oxidation
occurs at temperatures >790℃, resulting in molybdenum
trioxide, MoO3. Other common molybdenum compounds
commonly encountered include molybdenum trioxide,
sodium molybdate, Na2MoO4.2H2O, and ammonium di- and
heptamolybdate, (NH4)2Mo2O7, and (NH4)6Mo7O24.4H2O.
In aqueous solution, molybdenum is present as the simple
molybdate [MoO4]2- ion which is similar to sulfate or a polymeric
polymolybdate ion. The lower oxidation state is found in
the commonest ore of molybdenum the disulfide, MoS2. The
majority of atmospheric molybdenum emissions are anthropomorphic
sources such as its use in alloys, flame retardants,
smoke oppressors, catalysts, lubricants, and corrosion inhibitors,
and also by mining activities, the application of biosolids
and fertilizers, and atmospheric deposition from smelters. Coal
combustion is the largest atmospheric source of molybdenum.
In water, molybdenum exists primarily as the molybdate ion or
various polymeric compounds depending upon the pH. In
soils, molybdate is sorbed primarily to high-calcium, highchloride
soils with retention lesser in low-sulfate soils.
The primary pathway for molybdenum exposure is ingestion
by water or food. Molybdenum is found in leafy vegetables,
legumes, meat, and many grains. Molybdenum does not
appear to be absorbed dermally. Molybdenum dusts and
fumes, which can be generated by mining or metalworking,
may be inhaled. The concentrations of molybdenum in the
ambient air are normally low compared with other trace
elements; in urban areas, molybdenum ranged from 0.01 to
0.03 mg m-3, and in nonurban areas it varied between 0.001
and 0.0032 mg m-3. Fruits, root vegetables, and muscle meat
are poor sources of molybdenum; however, high concentrations
have been found in shellfish and fish, which contain
about 1 mg kg-1, and plants, which contain 0.03–5 mg kg-1.
Molybdenum levels in drinking water range from 0 to 68 μg l-1,
but usually do not exceed 10 μg l-1. Bioconcentration in most
fish appear to be exposure concentration dependent because it
has been demonstrated that at low environmental concentrations,
molybdenum is concentrated, whereas at high environmental
concentrations it is not concentrated. Molybdenum
levels are elevated in terrestrial flora near anthropomorphic
sources such as mining, fossil fuel plants, and industrial waste
sites. In these areas, the concentrations of molybdenum in
fish, wildlife, and invertebrates were low when compared with
those in terrestrial plants; therefore, there may be some bioconcentration
occurring in the flora. In addition, aquatic flora
and fauna seem to be comparatively resistant to molybdenum
salts and this evidence further indicates a lack of bioaccumulation
in fish. Molybdenum occurs naturally in soils at background concentrations ranging between 0.2 and 6 mg
kg-1, whereas metal-rich soils may contain 10–100 mg kg-1. | [storage]
Color Code—Green: General storage may be used.Prior to working with this chemical you should be trainedon its proper handling and storage. Molybdenum must bestored to avoid contact with strong oxidizers (such as chlorine, bromine, and fluorine) since violent reactions occur.Store in tightly closed containers in a cool, well-ventilatedarea away from bromine, trifluoride, fluorine, chlorine trifluoride, and lead dioxide. | [Toxicity evaluation]
Normally, enzymes containing molybdenum catalyze basic
metabolic reactions in the carbon, sulfur, and nitrogen cycles.
In plants, molybdenum acts as an enzyme activator for
nitrogen metabolism via reactions with nitrogenase, a nitrate
reductase. Consequently, molybdenum deficiency in legumes
produces effects similar to nitrogen deficiency. In mammals,
the types of reactions involving molybdenum-containing
enzymes include the transfer of oxygen atoms to or from the
electron pair of a substrate, and the oxidative hydroxylation of
aldehyde and aromatic compounds. Molybdenum is an
essential constituent of aldehyde oxidase, xanthine oxidase/
dehydrogenase, and sulfite oxidase, all of which catalyze
oxidation–reduction reactions. Molybdopterin maintains the
molybdenum atom to the active site of the protein in reactions
of the sulfur and carbon cycles. A deficiency of molybdopterin
has been associated with severe cerebral atrophy.
Molybdenosis or teart is a form of molybdenum toxicity
that produces a disease in ruminants similar to copper deficiency
in which trithiomolybdate ultimately alters the distribution
and elimination of copper. Signs of molybdenum
toxicity in animals include anemia, anorexia, profound diarrhea,
joint abnormalities, osteoporosis, hair discoloration,
reduced sexual activity, and death.
There is a paucity of data available on the human toxicity of
molybdenum. A goutlike syndrome and pneumoconiosis have
been associated with excessive concentrations of molybdenum,
but the inadequate design of the studies prevents an adequate
determination of the etiology of these effects. |
| Questions And Answer | Back Directory | [History, Occurrence, and Uses]
Molybdenum was first identified as a distinct element by Swedish chemist Karl Wilhelm Scheele in 1778. The metal was isolated by Hjelm in 1782 by reduction of its oxide with carbon. Moissan in 1895 isolated the metal in highly purified form by electrolytic reduction of its oxide and studied many of its physical and chemical properties. The element derived its name in 1816 from the word molybdos, meaning a soft mineral that appeared like lead.
Molybdenum does not occur in nature in free elemental form. Its most important ore is molybdenite, MoS2, from which the metal is obtained commercially. Other ores are powellite (calcium tungstomolybdate), Ca(MoW)O4, and wulfenite (lead molybdate), PbMoO4. The metal is an essential nutrient for plants and is found in trace amounts in some plants such as peas and beans, which absorb it from soil. Also, molybdenum is found in many natural petroleum oils.
The largest quantities of molybdenum produced are consumed in the steel industry. The metal is incorporated to steel to impart high resistance and hardness to the steel and to improve its mechanical properties. In the chemical industry, molybdenum compounds are used widely in coloring agents and solid lubricants. Molybdenum compounds are used also as catalysts in many oxidation-reduction reactions and in petroleum refining for production of high-octane gasoline. The metal also is used as the starting material to prepare many of its salts. Important commercial uses of molybdenum compounds are discussed separately under their individual headings.
| [Physical Properties]
Molybdenum is a silvery-white metal or grayish-black powder of the refractory metal family that is not normally found in its elemental state (Barceloux, 1999). cubic crystalline structure; density 10.22 g/cm3; melts at 2,623°C; vaporizes at 4,639°C; vapor pressure 1 torr at 2,830°C and 5 torr at 3,120°C; compressibility 3.6x10–7 cm2/kg at 20°C; electrical resistivity 5, 15, and 32 microhm–cm at 0°C, 400°C and 1,000°C, respectively; insoluble in water. | [Production]
Molybdenum is recovered primarily from its sulfide ore, molybdenite, MoS2. It also is produced, although to a much lesser extent, from the tungsten ore wulfenite, which yields lead molybdate, PbMoO4. The first phase of the recovery process generally involves concentration of the ore, because ore coming from the mine is very lean and usually contains less than one percent molybdenum. Molybdenite at first is concentrated by flotation which concentrates the MoS2 over 90%. If wulfenite is used as a source material, concentration is usually done by hydraulic methods.
The concentrated molybdenite ore is then roasted in air, converting molybdenum sulfide to molybdenum trioxide MoO3. This is harvested in high purity by sublimation. An alternative is to leach molybdenite concentrate with dilute ammonia solution, which converts the metal to ammonium molybdate, (NH4)2MoO4. Molybdenum trioxide or ammonium molybdate product is then heated with hydrogen at elevated temperatures from 500 to 1,150°C in a furnace to produce molybdenum powder.
| [Reactions]
Molybdenum is very stable to oxygen at ambient temperatures. However, when heated in air or oxygen to red heat the metal readily converts to its trioxide, MoO3:
2Mo + 3O2 → 2MoO3
Heating the finely divided metal with its trioxide at 750°C makes molybdenum pentoxide, Mo2O5:
Mo + MoO3 + O2 → Mo2O5
When heated in steam at 800°C, the metal is converted to its dioxide, MoO2:
Mo + 2H2O → MoO2 + 2H2
Molybdenum combines with fluorine gas at ordinary temperatures forming colorless hexafluoride, MoF6:
Mo + 3F2 → MoF6
In the presence of oxygen, an oxyfluoride MoOF4 is obtained:
2Mo + O2 + 4F2 → 2MoOF4
Reactions with chlorine and bromine occur only at elevated temperatures. With chlorine the product is molybdenum pentachloride:
2Mo + 5Cl2 → 2MoCl5
When bromine vapor is passed over molybdenum metal at 600 to 700°C in an atmosphere of nitrogen, the product is trimeric molybdenum dibromide (trimolybdenum hexabromide) (Mo3Br6):
3Mo + 3Br2 → Mo3Br6
Two other bromides are also obtained from the elements. These are molybdenum tribromide, MoBr3, and molybdenum tetrabromide, MoBr4. MoBr3, a black solid, is obtained by heating the elements at 350 to 400°C.
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