7429-90-5
Name | Aluminium |
CAS | 7429-90-5 |
EINECS(EC#) | 231-072-3 |
Molecular Formula | Al |
MDL Number | MFCD00134029 |
Molecular Weight | 26.98 |
MOL File | 7429-90-5.mol |
Synonyms
AE
AL
ADO
ad1
a00
a95
AR2
L16
AV00
aoa1
aoal
a995
a999
A 00
A 95
AD1M
AD 1
adom
ABPP
ABETA
Alaun
A 995
A 999
a999v
AO A1
AV000
E 173
Metana
aa1099
aa1193
AA1199
MTDPS5
AA 1099
ci77000
jisc3108
jisc3110
AL005110
AL003805
AL003860
AL003880
AL007030
AL003815
AL007975
AL007928
AL004950
AL002640
AL002540
AL002840
AL006830
AL002675
AL005105
AL005120
AL007031
AL002695
AL004915
AL007901
AL007924
AL007930
AL003802
AL005850
AL004925
AL007750
AL002510
AL007925
AL004700
AL007050
AL003835
AL005145
AL005162
AL005173
AL005180
AL007915
AL007100
AL007200
AL005172
AL005164
AL005155
AL005182
AL008721
AL002656
AL004075
AL004600
AL004850
AL005150
AL006810
AL007913
AL005200
AL006825
ALUMINUM
AL ALLOY
AL007920
AL006820
AL005137
AL002720
AL003826
AL002696
AL007912
AL005160
AL005183
AL002960
AL004990
AL003810
AL006860
AL005138
AL003845
AL005133
AL008710
AL007020
AL004500
AL005140
AL005185
AL005130
AL005250
AL007025
AL005176
AL002520
AL002940
AL002676
AL007040
AL002678
AL007950
AL005170
AL002655
AL005134
AL003825
AL007910
AL002910
AL007906
SCS-betaA
ALUMINIUN
ALUMINIUM
tube foil
c.i.77000
JISC 3108
JISC 3110
c-pigment1
C.I. 77000
aluminum27
ALLOY 1199
aluminum-27
aluminuma00
Aluminum 27
Aluminum A00
aluminafibre
Aluminum rod
'LGC' (2612)
aluminium(0)
aluminium(3+)
Aluminum slug
Aluminum shot
Aluminum wire
caswellno028a
Aluminum foil
Alumina fibre
aluminumflake
noralaluminum
ALUMINIUMDUST
MCINTYREPOWDER
Aluminum in B5
AluMinuM power
Al , AluMiniuM
noralaluminium
ALUMINUM METAL
aluminiumflake
Aluminum ingot
Nano-aluminium
Aluminium foil
Aluminium wire
ALUMINIUM NO 1
ALUMINIUM NO 2
Aluminium, rod
ALUMINUM ALLOY
aluminium atom
Aluminum, Hard
Aluminum sheet
Aluminium slice
Aluminium Ingot
Aluminium,piece
Aluminium, rods
Aluminium sheet
ALUMINUM BRONZE
AluminumshotNmm
ALUMINIUM METAL
ALUMINUM POWDER
aluminiumbronze
Aluminium flake
ALUMINIUMFIBRES
Aluminum in B20
Aluminium, chip
Aluminium tablet
Aluminum in B100
Aluminium, 99.5%
Aluminium bronze
Aluminium powder
ALUMINUM,PELLETS
ALUMINIUM GRITTY
mmAluminum Powder
Aluminumfoilmmxmm
Aluminumrod(99+%)
Aluminiumturnings
tube sealing foil
ALUMINUM STANDARD
ALUMINUM, 99.999%
AluMinuM solution
TSA/ MALT EXTRACT
Aluminum, Annealed
aluminum=aluminium
aluminumdehydrated
Aluminum (B, C, O)
ALUMINIUM STANDARD
ALUMINUM ULTRATHIN
Aluminium, turning
ALUMINUM, ATOMIZED
Aluminumpowdermesh
AluminumwireNmmdia
ALUMINUM, GRANULES
Aluminum activated
Aluminum granular
Aluminum sheet thin
ALUMINUM,SHOT,A.C.S
Al Target 99.999%
ALUMINUM BASE ALLOY
Aluminumfoil(99.9%)
Aluminium (B, C, O)
Aluminum dehydrated
metanaaluminumpaste
Aluminum shot, shot
aluminium(aluminum)
Aluminum metal foil
Aluminum ingot (Al)
Aluminum metal dust
Aluminum stick (Al)
K&H Aluminium Powder
ALMINIUM(PYROPOWDER)
Aluminum (all forms)
Aluminium thin sheet
ALUMINIUM,ACSREAGENT
Aluminumpowder(99+%)
AluminumrodNmmdiagcm
ALUMINUM AA STANDARD
Aluminumrod(99.9995%)
Aluminumshot(99.999%)
Aluminumpowder(99.7%)
Aluminumfoil(99.997%)
noralnon-leafinggrade
Aluminum foil (99.5%)
ALUMINUM,WIRE,REAGENT
ALUMINIUM FINE POWDER
aluminium,high purity
Aluminiumfoilmmxmmxmm
Aluminiumpowdercoarse
ALUMINUM ICP STANDARD
Aluminium, Shot 4-8mm
Metana aluminum paste
noralinkgradealuminum
Aluminum pyro powders
aluminumpowder,coated
noralinkgradealuminium
ALUMINIUM ICP STANDARD
Aluminum metal filings
ALUMINUMMETAL,GRANULAR
ALUMINUM, 99.999%, ROD
ALUMINUM 99.0%-99.999%
AQUANAL-PLUS ALUMINIUM
Aluminum wire annealed
Aluminumfoil(99.9995%)
Aluminumwire(99.9995%)
Aluminium, reagent ACS
Aluminum, shot, 4-8 mm
Aluminum Silver Powder
Aluminum Ultrathin foil
aluminium powder coated
Aluminium powder, 99.7%
Aluminium chunks, 99.9%
AluminumpowderNmeshgran
Aluminumfoilmmthickcmcm
OD50mm x ID44mm x 100mm
Aluminum metal turnings
ALUMINIUM(WELDINDFUMES)
ALUMINUM: 99.5%, POWDER
aluminumpowder,uncoated
Mini Bin? aluminum foil
AluMinuM wire,0.1MM dia.
AluMinuM wire,0.2MM dia.
AluMinuM wire,0.5MM dia.
AluMinuM wire,1.0MM dia.
AluMinuM wire,2.0MM dia.
MINERAL OIL AND ALUMINUM
AluminumingotNmetalingot
Aluminium, rods, 99.999%
ALUMINUM, INGOT, 99.997%
ALUMINUM, INGOT, 99.999%
Aluminium, 99.999%, rods
Aluminium, powder,99.99%
Aluminium ingot, 99.999%
Aluminium ingots, 99.99%
MERCURY 1,000PPM FOR ICP
Aluminum metal total dust
Aluminium, powder, 99.97%
Aluminium foil, GR, 99.9%
aluminium powder uncoated
Aluminum stick/ingot (Al)
Aluminium Granules 2-5 mm
Aluminium Granules 3-5 mm
Aluminium, 99.97%, powder
Aluminum, pellets, 1/41/2
Aluminum, pellets, 1/81/8
Aluminium, shot (2-10 mm)
Aluminium, turnings, 99+%
AluminumrodNmmdiaxmlonggm
AQUANAL(R)-PLUS ALUMINIUM
ALUMINUM: 99.5%, GRANULES
aluminumpowder,pyrophoric
ALUMINUM ICP/DCP STANDARD
noralextrafinelininggrade
Aluminum, pellets, 1/4x1/2
Aluminum, pellets, 1/4x1/4
Aluminum, pellets, 1/8x1/4
Aluminum, pellets, 1/8x1/8
Aluminium Pellets 6 x 6 mm
Aluminumfoilmmthickxmmwide
91889 ALUMINIUM (B C O)
79223 ALUMINIUM (B C O)
Aluminum,powder,coarse,99%
Aluminum, For analysis APS
Aluminium Granules 2-10 mm
ALUMINUM, 99.8%, FOIL, THIC
ALUMINUM, SHOT, 1-2MM DIAM.
AluminumrodNmmdiaxcmlonggcm
Aluminum, Quant Test Strips
ALUMINUMMETAL,POWDER200MESH
ALUMINIUM STANDARD SOLUTION
Aluminium solution 1000 ppm
Aluminum, powder, -100 Mesh
MANGANESE 10,000PPM FOR ICP
Aluminum, respirable (as Al)
Aluminum powder , flake (Al)
allbrialuminumpasteandpowder
ALUMINUM STANDARD SOLUTION R
ALUMINUM ANALYTICAL STANDARD
emanayatomizedaluminumpowder
ALUMINUM SHOT, REAGENT (ACS)
Aluminum, APS 3.0-4.5 micron
Aluminium Rod 25 mm diameter
Aluminium Rod 10 mm diameter
Aluminium Rod 6.0 mm diameter
Aluminium Powder < 250 micron
Aluminum, powder, coarse, 99%
Aluminium Rod 5.0 mm diameter
Aluminumwireannealed(99.999%)
Aluminum dust, Aluminum metal
Aluminium solution 10 000 ppm
Aluminium Granules 0.6-1.2 mm
Aluminum shot (99.999%)5-7 mm
Aluminium, shot 4-8mm 99.999%
Aluminum powder , sphere (Al)
aluminium powder (pyrophoric)
Alumina Refractory Repair mix
Aluminium, dia.6 x 6 mm, 99.9%
Aluminum metal respirable dust
ALUMINIUM (GRIT) FOR SYNTHESIS
ALUMINUM, FLAKES, 0.6MM, 99.9%
Aluminium Powder < 1000 micron
Aluminium Pellets 3.9 x 2.5 mm
Aluminium Pellets 9.5 x 3.2 mm
Aluminium Wire 5.0 mm diameter
Aluminium Pellets 1.6 x 0.5 mm
Aluminium Wire 0.5 mm diameter
Aluminium Wire 1.0 mm diameter
Aluminium Wire 2.0 mm diameter
Aluminum, APS 10.0-14.0 micron
epapesticidechemicalcode000111
Emanay atomized aluminum powder
Chemical Properties
Appearance | Aluminum is a combustible, light, silverywhite, soft, ductile, malleable, amphoteric metal |
Melting point | 660.37 °C (lit.) |
Boiling point | 2460 °C (lit.) |
density | 2.7 g/mL at 25 °C(lit.) |
vapor pressure | 0.13-1300Pa at 974℃ |
Fp | 400°C |
storage temp. | Flammables area |
solubility | insoluble in H2O; soluble in acid solutions, alkaline solutions |
form | wire |
color | Yellow |
Specific Gravity | 2.702 (Water=1) |
Odor | Odorless |
PH | 0.5 (H2O, 20°C) |
Stability: | Stable. Powder is flammable. Reacts very exothermically with halogens. Moisture and air sensitive. Incompatible with strong acids, caustics, strong oxidizing agents, halogenated hydrocarbons. |
Resistivity | 2.6548 μΩ-cm |
Water Solubility | Insoluble in water. |
Sensitive | Moisture Sensitive |
Merck | 13,321/13,321 |
Dielectric constant | 1.6-1.8(0.0℃) |
Exposure limits | TLV-TWA 10 mg/m3 (Al dust), 5 mg/m3 (pyrophoric Al powder and welding fumes), 2 mg/m3 (soluble Al salts and alkyls) (ACGIH). |
History | The ancient Greeks and Romans used alum in medicine as an astringent, and as a mordant in dyeing. In 1761 de Morveau proposed the name alumine for the base in alum, and Lavoisier, in 1787, thought this to be the oxide of a still undiscovered metal. Wohler is generally credited with having isolated the metal in 1827, although an impure form was prepared by Oersted two years earlier. In 1807, Davy proposed the name alumium for the metal, undiscovered at that time, and later agreed to change it to aluminum. Shortly thereafter, the name aluminium was adopted to conform with the “ium” ending of most elements, and this spelling is now in use elsewhere in the world. Aluminium was also the accepted spelling in the U.S. until 1925, at which time the American Chemical Society officially decided to use the name aluminum thereafter in their publications. The method of obtaining aluminum metal by the electrolysis of alumina dissolved in cryolite was discovered in 1886 by Hall in the U.S. and at about the same time by Heroult in France. Cryolite, a natural ore found in Greenland, is no longer widely used in commercial production, but has been replaced by an artificial mixture of sodium, aluminum, and calcium fluorides. Bauxite, an impure hydrated oxide ore, is found in large deposits in Jamaica, Australia, Suriname, Guyana, Russia, Arkansas, and elsewhere. The Bayer process is most commonly used today to refine bauxite so it can be accommodated in the Hall–Heroult refining process used to make most aluminum. Aluminum can now be produced from clay, but the process is not economically feasible at present. Aluminum is the most abundant metal to be found in the Earth’s crust (8.1%), but is never found free in nature. In addition to the minerals mentioned above, it is found in feldspars, granite, and in many other common minerals. Twenty-two isotopes and isomers are known. Natural aluminum is made of one isotope, 27Al. Pure aluminum, a silvery- white metal, possesses many desirable characteristics. It is light, nontoxic, has a pleasing appearance, can easily be formed, machined, or cast, has a high thermal conductivity, and has excellent corrosion resistance. It is nonmagnetic and nonsparking, stands second among metals in the scale of malleability, and sixth in ductility. It is extensively used for kitchen utensils, outside building decoration, and in thousands of industrial applications where a strong, light, easily constructed material is needed. Although its electrical conductivity is only about 60% that of copper, it is used in electrical transmission lines because of its light weight. Pure aluminum is soft and lacks strength, but it can be alloyed with small amounts of copper, magnesium, silicon, manganese, and other elements to impart a variety of useful properties. These alloys are of vital importance in the construction of modern aircraft and rockets. Aluminum, evaporated in a vacuum, forms a highly reflective coating for both visible light and radiant heat. These coatings soon form a thin layer of the protective oxide and do not deteriorate as do silver coatings. They have found application in coatings for telescope mirrors, in making decorative paper, packages, toys, and in many other uses. The compounds of greatest importance are aluminum oxide, the sulfate, and the soluble sulfate with potassium (alum). The oxide, alumina, occurs naturally as ruby, sapphire, corundum, and emery, and is used in glassmaking and refractories. Synthetic ruby and sapphire have found application in the construction of lasers The Elements 4-3 for producing coherent light. In 1852, the price of aluminum was about $1200/kg, and just before Hall’s discovery in 1886, about $25/kg. The price rapidly dropped to 60¢ and has been as low as 33¢/kg. The price in December 2001 was about 64¢/ lb or $1.40/kg. |
CAS DataBase Reference | 7429-90-5(CAS DataBase Reference) |
NIST Chemistry Reference | Aluminum(7429-90-5) |
EPA Substance Registry System | 7429-90-5(EPA Substance) |
Safety Data
Hazard Codes | F,Xi,Xn |
Risk Statements |
R17:Spontaneously flammable in air.
R15:Contact with water liberates extremely flammable gases. R36/38:Irritating to eyes and skin . R10: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. R11:Highly Flammable. |
Safety Statements |
S7/8:Keep container tightly closed and dry .
S43:In case of fire, use ... (indicate in the space the precise type of fire-fighting equipment. If water increases the risk add-Never use water) . S26:In case of contact with eyes, rinse immediately with plenty of water and seek medical advice . 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 . S33:Take precautionary measures against static discharges . S29:Do not empty into drains . S16:Keep away from sources of ignition-No smoking . S9:Keep container in a well-ventilated place . |
RIDADR | 1396 |
WGK Germany | 3 |
RTECS | BD0330000 |
Autoignition Temperature | 400 °C |
TSCA | Yes |
HazardClass | 8 |
PackingGroup | III |
HS Code | 76032000 |
storage | Aluminum metallic powder should be kept stored in a tightly closed container, in a cool, dry, ventilated area, protected against physical damage and isolated from sources of heat, ignition, smoking areas, and moisture. Aluminum metallic powder should be kept away from acidic, alkaline, combustible, and oxidizing materials and separate from halogenated compounds. |
Precautions | The dry powder is stable but the damp or moist bulk dust may heat spontaneously and form flammable hydrogen gas. Moist aluminum powder may ignite in air, with the formation of flammable hydrogen gas and a combustible dust. Powdered material may form explosive dust-air mixtures. Contact with water, strong acids, strong bases, or alcohols releases flammable hydrogen gas. The dry powder can react violently or explosively with many inorganic and organic chemicals |
Safety Profile |
Although aluminum is not generally regarded as an industrial poison, inhalation of finely dwided powder has been reported to cause pulmonary fibrosis. It is a reactive metal and the greatest industrial hazards are with chemical reactions. As with other metals the powder and dust are the most dangerous forms. Dust is moderately flammable and explosive by heat, flame, or chemical reaction with powerful oxidizers. To fight fire, use special mixtures of dry chemical.
following dangerous interactions: explosive reaction after a delay period with KClO4 + Ba(NO3)2 + mo3 + H20, also with Ba(NO3)2 + mo3 + sulfur + vegetable adhesives + H2O. Wxtures with powdered AgCl, NH4NO3 or NH4NO3 + Ca(NO3)2 + formamide + H20 are powerful explosives. Murture with ammonium peroxodisulfate + water is explosive. Violent or explosive "thermite" reaction when heated with metal oxides, oxosalts (nitrates, sulfates), or sulfides, and with hot copper oxide worked with an iron or steel tool. Potentially explosive reaction with ccl4 during ball milling operations. Many violent or explosive reactions with the following halocarbons have occurred in industry: bromomethane, bromotrifluoromethane, ccl4, chlorodfluoromethane, chloroform, chloromethane, chloromethane + 2methylpropane, dchlorodifluoromethane, 1,2-dichloroethane, dichloromethane, 1,2dichloropropane, 1,2-difluorotetrafluoroethane, fluorotrichloroethane, hexachloroethane + alcohol, polytrifluoroethylene oils and greases, tetrachloroethylene, tetrafluoromethane, 1,1,1trichloroethane, trichloroethylene, 1,1,2trichlorotrifluoro-ethane, and trichlorotrifluoroethane-dchlorobenzene. Potentially explosive reaction with chloroform amidinium nitrate. Ignites on contact with vapors of AsCl3, SC4, Se2Cl2, and PCl5. Reacts violently on heating with Sb or As. Ignites on heating in SbCl3 vapor. Ignites on contact with barium peroxide. Potentially violent reaction with sodium acetylide. Mixture with sodum peroxide may ignite or react violently. Spontaneously igmtes in CS2 vapor. Halogens: ignites in Powdered aluminum undergoes the
chlorine gas, foil reacts vigorously with liquid Br2, violent reaction with H20 + 12. Violent reaction with hydrochloric acid, hydro-fluoric acid, and hydrogen chloride gas. Violent reaction with disulfur dbromide. Violent reaction with the nonmetals phosphorus, sulfur, and selenium. Violent reaction or ignition with the interhalogens: bromine pentafluoride, chlorine fluoride, iodne chloride, iodine pentafluoride, and iodne heptafluoride. Burns when heated in CO2. Ignites on contact with O2, and mixtures with O2 + H20 ignite and react violently. Mixture with picric acid + water ignites after a delay period. Explosive reaction above 800°C with sodium sulfate. Violent reaction with sulfur when heated. Exothermic reaction with iron powder + water releases explosive hydrogen gas. Aluminum powder also forms sensitive explosive mixtures with oxidants such as: liquid Cl2 and other halogens, N2O4, tetranitromethane, bromates, iodates, NaClO3, KClO3, and other chlorates, NaNO3, aqueous nitrates, KClO4 and other perchlorate salts, nitryl fluoride, ammonium peroxodisulfate, sodium peroxide, zinc peroxide, and other peroxides, red phosphorus, and powdered polytetrafluoroethylene (PTFE).
following dangerous interactions: exothermic reaction with butanol, methanol, 2-propanol, or other alcohols, sodium hydroxide to release explosive hydrogen gas. Reaction with dborane forms pyrophoric product. Ignition on contact with niobium oxide + sulfur. Explosive reaction with molten metal oxides, oxosalts (nitrates, sulfates), sulfides, and sodium carbonate. Reaction with arsenic trioxide + sodum arsenate + sodium hydroxide produces the toxic arsine gas. Violent reaction with chlorine trifluoride. Incandescent reaction with formic acid. Potentially violent alloy formation with palladium, platinum at mp of Al, 600℃. Vigorous dssolution reaction in Bulk aluminum may undergo the
ALUMINUM CHLORIDE HYDROXIDE AHAOOO 45
methanol + carbon tetrachloride. Vigorous amalgamation reaction with mercury(Ⅱ) salts + moisture. Violent reaction with molten silicon steels. Violent exothermic reaction above 600℃ with sodium diuranate.
|
Hazardous Substances Data | 7429-90-5(Hazardous Substances Data) |
Toxicity |
An element that is
abundant (about 8%) in the crust of the earth. Aluminum
appears to have no biological function and, from the point of
view of acute toxicity, is essentially non-toxic. Because it is
primarily eliminated by excretion, people with compromised
kidney function may accumulate the metal. In kidney dialysis
patients, this is a particular problem because the dialyzing
solution may contain high concentrations of aluminum. This
condition (dialysis encephalopathy or dialysis dementia) has
symptoms that include impaired memory, EEG changes,
dementia, aphasia, ataxia, and convulsions.One possible
mechanism of toxicity may be inhibition of hexokinases in the
brain. The chelating agent deferoxamine has been used successfully
in treating this condition.Aluminum is one of the primary toxicants leached
into surface water (and, therefore, water supplies) by acid
deposition. The connection between aluminum and Alzheimers
disease is controversial and many investigators believe there is
no connection.
|
Raw materials And Preparation Products
Preparation Products
- polyethylene conductive plastics
- Aluminum chlorohydrate
- 2,6-Diethylaniline
- 1-Naphthalene acetic acid
- Decabromodiphenyl oxide
- 5-CHLORO-1H-INDAZOLE-3-CARBOXYLIC ACID
- DIETHYLALUMINUM CHLORIDE
- Econazole
- Iopanoic acid
- Miconazole nitrate
- Aluminum nitrate
- 3-(1,2,2,2-tetrabromoethyl)-2,2-dimethyl cyclo-propane carboxylic acid
- Titanous chloride
- Iodotrimethylsilane
- Triethylaluminum
- ALUMINUM POTASSIUM SULFATE
- N-Methylcyclohexylamine
- CALCIUM PHOSPHIDE
- Aluminate coupling agent
- Aluminum phosphide
1of8
Hazard Information
Chemical Properties
Aluminum is the most commonly available element in homes and workplaces. Aluminum
is readily available for human ingestion through the use of food additives, antacids, buffered aspirin, astringents, nasal sprays, and antiperspirants; from drinking water; from automobile exhaust and tobacco smoke; and from using aluminum foil, aluminum cookware,
cans, ceramics, and fi reworks. Aluminum toxicity and its association with Alzheimer’s
disease in humans require more studies. Some data are against and some are for, because
the evidences are inadequate and inconclusive to suggest aluminum as the primary cause
of the disease. Prolonged periods of exposure to aluminum and dust causes coughing,
wheezing, shortness of breath, memory loss, learning diffi culty, loss of coordination, disorientation, mental confusion, colic, heartburn, fl atulence, and headaches. Chronic exposures to alumina dust cause irritation to the eyes, skin, respiratory system, pulmonary
fi brosis, and lung damage
Chemical Properties
Aluminum metallic powder is a light, silvery-white to gray, odorless powder. Aluminum
metallic powder is reactive and flammable. Aluminum is normally coated with a layer of
aluminum oxide unless the particles are freshly formed. There are two main types of aluminum powder: the “fl ake” type made by stamping the cold metal and the “granulated”
type made from molten aluminum. Pyro powder is an especially fi ne type of “fl ake”
powder. Aluminum powders are used in paints, pigments, protective coatings, printing
inks, rocket fuel, explosives, abrasives, and ceramics; the production of inorganic and
organic aluminum chemicals; and as catalysts. Pyro powder is mixed with carbon and
used in the manufacture of fi reworks. The coarse powder is used in aluminothermics.
General Description
Aluminum metal held above melting point of 1220°F (660°C) for ease in handling. Cools and solidifies if released. Contact causes thermal burns. Plastic or rubber may melt or lose strength upon contact. Protective equipment designed for chemical exposure only is not effective against direct contact. Take care walking on the surface of a spill to avoid stepping into a pocket of molten aluminum below the crust. Do not attempt to remove aluminum impregnated clothing because of the danger of tearing flesh if there has been a burn.
Reactivity Profile
ALUMINUM , MOLTEN, is a reducing agent. Coating moderates or greatly moderates its chemical reactivity compared to the uncoated material. Reacts exothermically if mixed with metal oxides and heated (thermite process). Heating a mixture with copper oxides caused a strong explosion [Mellor 5:217-19 1946-47]. Reacts with metal salts, mercury and mercury compounds, nitrates, sulfates, halogens, and halogenated hydrocarbons to form compounds that are sensitive to mechanical shock [Handling Chemicals Safely 1980. p. 135]. A number of explosions in which ammonium nitrate and powdered aluminum were mixed with carbon or hydrocarbons, with or without oxidizing agents, have occurred [Mellor 5:219 1946-47]. A mixture with powdered ammonium persulfate and water may explode [NFPA 491M 1991]. Heating a mixture with bismuth trioxide leads to an explosively violent reaction [Mellor 9:649 (1946-47)]. Mixtures with finely divided bromates(also chlorates and iodates) of barium, calcium, magnesium, potassium, sodium or zinc can explode by heat, percussion, and friction, [Mellor 2:310 (1946-47]. Burns in the vapor of carbon disulfide, sulfur dioxide, sulfur dichloride, nitrous oxide, nitric oxide, or nitrogen peroxide, [Mellor 5:209-212,1946-47]. A mixture with carbon tetrachloride exploded when heated to 153° C and also by impact, [Chem. Eng. News 32:258 (1954)]; [UL Bull. Research 34 (1945], [ASESB Pot. Incid. 39 (1968)]. Mixing with chlorine trifluoride in the presence of carbon results in a violent reaction [Mellor 2 Supp. 1: 1956]. Ignites in close contact with iodine. Three industrial explosions involving a photoflash composition containing potassium perchlorate with aluminum and magnesium powder have occurred [ACS 146:210 1945], [NFPA 491M 1991]. Is attacked by methyl chloride in the presence of small amounts of aluminum chloride to give flammable aluminum trimethyl. Give a detonable mixture with liquid oxygen [NFPA 491M 1991]. The reaction with silver chloride, once started, proceeds with explosive violence [Mellor 3:402 1946-47]. In an industrial accident, the accidental addition of water to a solid mixture of sodium hydrosulfite and powdered aluminum caused the generation of SO2, heat and more water. The aluminum powder reacted with water and other reactants to generate more heat, leading to an explosion that killed five workers [Case Study, Accident Investigation: Napp Technologies, 14th International Hazardous Material Spills Conference].
Air & Water Reactions
Violent reaction with water; contact may cause an explosion or may produce a flammable gas (hydrogen). Moist air produces hydrogen gas. Does not burn on exposure to air.
Hazard
Fine powder forms flammable and explo-
sive mixtures in air. Confirmed carcinogen.
Health Hazard
Contact causes severe burns to skin and eyes. Fire may produce irritating and/or toxic gases.
Health Hazard
Exposures to aluminum metallic powder have been known to cause health effects with
symptoms such as irritation, redness, and pain to the eyes, coughing, shortness of breath,
irritation to the respiratory tract, nausea, and vomiting in extreme cases. In prolonged
periods of inhalation exposures, as in occupational situations, aluminum metallic powder
is known to cause pulmonary fi brosis, numbness in fi ngers, and (in limited cases) brain
effects. Workers with pre-existing skin disorders, eye problems, or impaired respiratory
function are known to be more susceptible to the effects of aluminum metallic powder.
Health Hazard
Occupational exposure to aluminum dust and fumes during welding provide suggestive
evidence that there may be a relationship between chronic aluminum exposure and subclinical neurological effects, such as impairment on neurobehavioral tests for psychomotor and cognitive performance. Inhalation exposure has not been associated with overt
symptoms of neurotoxicity. Prolonged exposure to high concentrations of aluminum and
its accumulation causes disturbances in renal function, dialysis, and encephalopathy
syndrome—a degenerative neurological syndrome characterized by the gradual loss of
motor, speech, and cognitive functions
Potential Exposure
Most hazardous exposures to aluminum occur in smelting and refining processes. Aluminum is mostly produced by electrolysis of Al2O3 dissolved in molten cryolite (Na3AlF6). Aluminum is alloyed with copper, zinc, silicon, magnesium, manganese, and nickel; special additives may include chromium, lead, bismuth, titanium, zirconium, and vanadium. Aluminum and its alloys can be extruded or processed in rolling mills, wire works, forges, or foundries; and are used in the shipbuilding, electrical, building, aircraft, automobile, light engineering, and jewelry industries. Aluminum foil is widely used in packaging. Powdered aluminum is used in the paints and pyrotechnic industries. Alumina, emery, and corundum has been used for abrasives, refractories, and catalysts; and in the past in the first firing of china and pottery.
Fire Hazard
Substance is transported in molten form at a temperature above 705°C (1300°F). Violent reaction with water; contact may cause an explosion or may produce a flammable gas. Will ignite combustible materials (wood, paper, oil, debris, etc.). Contact with nitrates or other oxidizers may cause an explosion. Contact with containers or other materials, including cold, wet or dirty tools, may cause an explosion. Contact with concrete will cause spalling and small pops.
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
UN1309 Aluminum powder, coated, Hazard Class: 4.1; Labels: 4.1-Flammable solid. UN1383 Pyrophoric metals, n.o.s. or Pyrophoric alloys, n.o.s., Hazard Class: 4.2; Labels: 4.2-Spontaneously combustible material, Technical Name Required. UN1396 Aluminum powder, uncoated, Hazard Class: 4.3; Labels: 4.3-Dangerous when wet material. NA9260 (North America) Aluminum, molten, Hazard class: 9; Labels: 9-Miscellaneous hazardous material.
Incompatibilities
Aluminum powder forms an explosive mixture with air and is a strong reducing agent that reacts violently with oxidizers, strong bases; strong acids; somehalogenated hydrocarbons; nitrates, sulfates, metal oxides and many other substances. Keep away from combustible materials.
Waste Disposal
Consult with environmental regulatory agencies for guidance on acceptable disposalpractices. Generators of waste containing this contaminant (≥100 kg/mo) must conform with EPA regulations governing storage, transportation, treatment, and waste disposal of Aluminum Oxide-Disposal in a sanitary landfill. Mixing of industrial process wastes and municipal wastes at such sites is not encouraged however. Aluminum powder may be recovered and sold as scrap. Recycling and recovery is a viable option to disposal for aluminum metal and aluminum fluoride (A-57).
Physical properties
Pure metallic aluminum is not found in nature. It is found as a part of compounds,especially compounded with oxygen as in aluminum oxide (Al2O3). In its purified form, aluminumis a bluish-white metal that has excellent qualities of malleability and ductility. Purealuminum is much too soft for construction or other purposes. However, adding as little as1% each of silicon and iron will make aluminum harder and give it strength.
Its melting point is 660.323°C, its boiling point is 2,519°C, and its density is 2.699 g/cm3.
Its melting point is 660.323°C, its boiling point is 2,519°C, and its density is 2.699 g/cm3.
Isotopes
There are 23 isotopes of aluminum, and only one of these is stable. The singlestable isotope, Al-27, accounts for 100% of the element’s abundance in the Earth’scrust. All the other isotopes are radioactive with half-lives ranging from a few nanosecondsto 7.17×10+15 years.
Origin of Name
From the Latin word alumen, or aluminis, meaning “alum,” which is a
bitter tasting form of aluminum sulfate or aluminum potassium sulfate.
Occurrence
Aluminum is the third most abundant element found in the Earth’s crust. It is found inconcentrations of 83,200 ppm (parts-per-million) in the crust. Only the nonmetals oxygenand silicon are found in greater abundance. Aluminum oxide (Al2O3) is the fourth mostabundant compound found on Earth, with a weight of 69,900 ppm. Another alum-typecompound is potassium aluminum sulfate [KAl(SO4)2?12H2O]. Although aluminum is notfound in its free metallic state, it is the most widely distributed metal (in compound form) onEarth. Aluminum is also the most abundant element found on the moon.
Almost all rocks contain some aluminum in the form of aluminum silicate minerals foundin clays, feldspars, and micas. Today, bauxite is the major ore for the source of aluminummetal. Bauxite was formed eons ago by the natural chemical reaction of water, which thenformed aluminum hydroxides. In addition to the United States, Jamaica and other Caribbeanislands are the major sources of bauxite. Bauxite deposits are found in many countries, butnot all are of high concentration.
Almost all rocks contain some aluminum in the form of aluminum silicate minerals foundin clays, feldspars, and micas. Today, bauxite is the major ore for the source of aluminummetal. Bauxite was formed eons ago by the natural chemical reaction of water, which thenformed aluminum hydroxides. In addition to the United States, Jamaica and other Caribbeanislands are the major sources of bauxite. Bauxite deposits are found in many countries, butnot all are of high concentration.
Characteristics
Alloys of aluminum are light and strong and can easily be formed into many shapes—thatis, it can be extruded, rolled, pounded, cast, and welded. It is a good conductor of electricityand heat. Aluminum wires are only about 65% as efficient in conducting electricity as arecopper wires, but aluminum wires are significantly lighter in weight and less expensive thancopper wires. Even so, aluminum wiring is not used in homes because of its high electricalresistance, which can build up heat and may cause fires.
Aluminum reacts with acids and strong alkali solutions. Once aluminum is cut, the freshsurface begins to oxidize and form a thin outer coating of aluminum oxide that protects themetal from further corrosion. This is one reason aluminum cans should not be discarded inthe environment. Aluminum cans last for many centuries (though not forever) because atmosphericgases and soil acids and alkalis react slowly with it. This is also the reason aluminumis not found as a metal in its natural state.
Aluminum reacts with acids and strong alkali solutions. Once aluminum is cut, the freshsurface begins to oxidize and form a thin outer coating of aluminum oxide that protects themetal from further corrosion. This is one reason aluminum cans should not be discarded inthe environment. Aluminum cans last for many centuries (though not forever) because atmosphericgases and soil acids and alkalis react slowly with it. This is also the reason aluminumis not found as a metal in its natural state.
Uses
Aluminum finds wide applications for industrialand domestic purposes. Fine powder isused in explosives, in fireworks, as flashlightsin photography, and in aluminumpaints. It is commonly used in alloys withother metals and is nonhazardous as alloys.
Uses
Aluminum is a very versatile metal with many uses in today’s economy, the most common ofwhich are in construction, in the aviation-space industries, and in the home and automobile industries.Its natural softness is overcome by alloying it with small amounts of copper or magnesium thatgreatly increase its strength. It is used to make cans for food and drinks, in pyrotechnics, for protectivecoatings, to resist corrosion, to manufacture die-cast auto engine blocks and parts, for homecooking utensils and foil, for incendiary bombs, and for all types of alloys with other metals.
Aluminum does not conduct electricity as well as copper, but because it is much lighter inweight, it is used for transmission lines, though not in household wiring. A thin coating ofaluminum is spread on glass to make noncorroding mirrors. Pure oxide crystals of aluminumare known as corundum, which is a hard, white crystal and one of the hardest substancesknown. Corundum finds many uses in industry as an abrasive for sandpaper and grindingwheels. This material also resists heat and is used for lining high-temperature ovens, to formthe white insulating part of spark plugs, and to form a protective coating on many electronicdevices such a transistors.Aluminum oxide is used to make synthetic rubies and sapphires for lasers beams. It hasmany pharmaceutical uses, including ointments, toothpaste, deodorants, and shaving creams.
Aluminum does not conduct electricity as well as copper, but because it is much lighter inweight, it is used for transmission lines, though not in household wiring. A thin coating ofaluminum is spread on glass to make noncorroding mirrors. Pure oxide crystals of aluminumare known as corundum, which is a hard, white crystal and one of the hardest substancesknown. Corundum finds many uses in industry as an abrasive for sandpaper and grindingwheels. This material also resists heat and is used for lining high-temperature ovens, to formthe white insulating part of spark plugs, and to form a protective coating on many electronicdevices such a transistors.Aluminum oxide is used to make synthetic rubies and sapphires for lasers beams. It hasmany pharmaceutical uses, including ointments, toothpaste, deodorants, and shaving creams.
Uses
As pure metal or alloys (magnalium, aluminum bronze, etc.) for structural material in construction, automotive, electrical and aircraft industries. In cooking utensils, highway signs, fencing, containers and packaging, foil, machinery, corrosion resistant chemical equipment, dental alloys. The coarse powder in aluminothermics (thermite process); the fine powder as flashlight in photography; in explosives, fireworks, paints; for absorbing occluded gases in manufacture of steel. In testing for Au, As, Hg; coagulating colloidal solutions of As or Sb; pptg Cu; reducer for determining nitrates and nitrites; instead of Zn for generating hydrogen in testing for As. Forms complex hydrides with lithium and boron, such as LiAlH4, which are used in preparative organic chemistry.
Definition
aluminium: Symbol Al. A silverywhitelustrous metallic element belongingto group 3 (formerly IIIB) ofthe periodic table; a.n. 13; r.a.m.26.98; r.d. 2.7; m.p. 660°C; b.p.2467°C. The metal itself is highly reactivebut is protected by a thintransparent layer of the oxide, whichforms quickly in air. Aluminium andits oxide are amphoteric. The metalis extracted from purified bauxite(Al2O3) by electrolysis; the mainprocess uses a Hall–Heroult cell butother electrolytic methods are underdevelopment, including conversionof bauxite with chlorine and electrolysisof the molten chloride. Pure aluminiumis soft and ductile but itsstrength can be increased by workhardening.A large number of alloysare manufactured; alloying elementsinclude copper, manganese, silicon,zinc, and magnesium. Its lightness,strength (when alloyed), corrosion resistance,and electrical conductivity(62% of that of copper) make it suitablefor a variety of uses, includingvehicle and aircraft construction,building (window and door frames),and overhead power cables. Althoughit is the third most abundantelement in the earth’s crust (8.1% byweight) it was not isolated until 1825by H. C. Oersted.
Agricultural Uses
Aluminum, the third most abundant element in the earth’s
crust, is a silvery-white lustrous metal belonging to
Group 13 of the Periodic Table. The metal is
highly reactive and is protected by a thick transparent
oxide layer that gets formed quickly in air. Aluminum
and its oxides are amphoteric.
Pure aluminum, which exists in a large number of alloys, is extracted from purified bauxite by electrolysis. Its lightness, strength (when alloyed), corrosion resistance and electrical conductivity make aluminum suitable for a variety of uses, including in the construction of vehicles, aircrafts, buildings and overhead power cables.
Aluminum (Al) is an important soil constituent. It is toxic to most plants at a soil pH below 6.0.
Aluminum ion forms octahedral coordination with water molecules and hydroxyl ions. If soil is not strongly acidic, one (or more) of the water molecules ionizes, releasing the hydrogen ion (H+)in to the solution and increasing the soil acidity.
The toxic level of soluble and exchangeable aluminum can be substantially reduced by first raising the soil pH in the range of 5.2 to 5.5 and by further liming to make it in the range of 6.0 to 6.5.
In acidic soils, aluminum may compete for uptake with copper and make the soil copper deficient. Molybdenum is adsorbed strongly by oxides of aluminum and iron, thereby making the molybdenum unavailable to plants. Increasing aluminum in the soil solution also restricts the uptake of calcium and magnesium by plants.
Aluminum ions are toxic to the roots of many plants such as cotton, tomato, alfalfa, celery, barley, corn, sorghum, and sugar beets. Aluminum toxicity is probably the most important growth limiting factor in many acid soils.
The symptoms of aluminum toxicity caused by excess soluble aluminum are not easily recognize in crop plants. White-yellow interveinal blotches form on leaves causing them to dry out and die. Aluminum toxicity also reduces the growth of both shoots and roots.
An excess of aluminum interferes with cell division in plant roots, inhibits nodule initiation (by fixing the soil phosphorus to forms that are less available to plant roots), and decreases root respiration. Aluminum interferes with enzymes controlling the deposition of polysaccharides in cell walls and increases cell wall rigidity by cross-linking with pectins. It reduces the uptake, transport, and use of nutrients and water by the plant.
Aluminum-injured roots are characteristically stubby and brittle. The root tips and lateral roots thicken and turn brown. The root system as a whole, appears coralline, with many stubby lateral roots but no fine branching.
The toxicity problem of aluminum is not economically correctable with conventional liming practices. A genetic approach has the potential to solve the problem of aluminum toxicity in acid soils.
Pure aluminum, which exists in a large number of alloys, is extracted from purified bauxite by electrolysis. Its lightness, strength (when alloyed), corrosion resistance and electrical conductivity make aluminum suitable for a variety of uses, including in the construction of vehicles, aircrafts, buildings and overhead power cables.
Aluminum (Al) is an important soil constituent. It is toxic to most plants at a soil pH below 6.0.
Aluminum ion forms octahedral coordination with water molecules and hydroxyl ions. If soil is not strongly acidic, one (or more) of the water molecules ionizes, releasing the hydrogen ion (H+)in to the solution and increasing the soil acidity.
The toxic level of soluble and exchangeable aluminum can be substantially reduced by first raising the soil pH in the range of 5.2 to 5.5 and by further liming to make it in the range of 6.0 to 6.5.
In acidic soils, aluminum may compete for uptake with copper and make the soil copper deficient. Molybdenum is adsorbed strongly by oxides of aluminum and iron, thereby making the molybdenum unavailable to plants. Increasing aluminum in the soil solution also restricts the uptake of calcium and magnesium by plants.
Aluminum ions are toxic to the roots of many plants such as cotton, tomato, alfalfa, celery, barley, corn, sorghum, and sugar beets. Aluminum toxicity is probably the most important growth limiting factor in many acid soils.
The symptoms of aluminum toxicity caused by excess soluble aluminum are not easily recognize in crop plants. White-yellow interveinal blotches form on leaves causing them to dry out and die. Aluminum toxicity also reduces the growth of both shoots and roots.
An excess of aluminum interferes with cell division in plant roots, inhibits nodule initiation (by fixing the soil phosphorus to forms that are less available to plant roots), and decreases root respiration. Aluminum interferes with enzymes controlling the deposition of polysaccharides in cell walls and increases cell wall rigidity by cross-linking with pectins. It reduces the uptake, transport, and use of nutrients and water by the plant.
Aluminum-injured roots are characteristically stubby and brittle. The root tips and lateral roots thicken and turn brown. The root system as a whole, appears coralline, with many stubby lateral roots but no fine branching.
The toxicity problem of aluminum is not economically correctable with conventional liming practices. A genetic approach has the potential to solve the problem of aluminum toxicity in acid soils.
Industrial uses
Alloying aluminum with various elementsmarkedly improves mechanical properties,strength primarily, at only a slight sacrifice indensity, thus increasing specific strength, orstrength-to-weight ratio. Traditionally, wroughtalloys have been produced by thermomechanicallyprocessing cast ingot into mill productssuch as billet, bar, plate, sheet, extrusions, andwire. For some alloys, however, such mill productsare now made by similarly processing“ingot” consolidated from powder. Such alloysare called PM (powder metal) wrought alloysor simply PM alloys. To distinguish the traditionaltype from these, they are now sometimesreferred to as ingot-metallurgy (IM) alloys oringot-cast alloys. Another class of PM alloysare those used to make PM parts by pressingand sintering the powder to near-net shape.There are also many cast alloys. All told, thereare about 100 commercial aluminum alloys.
Carcinogenicity
Most animal studies have failed to demonstrate carcinogenicity
attributable to aluminum administered by various
routes in rats, rabbits, mice, and guinea pigs. Some of
these studies even suggested some antitumor activity.
However, aluminum was found to cause cancer in a few
experimental studies such as sarcomas in rats when
implanted subcutaneously. This observation was attributed
to the dimensions of the implants rather than the
chemical composition.
Significantly increased incidence of gross tumors was reported in male Long Evans rats and lymphoma leukemia in female Swiss mice given aluminum potassium sulfate in drinking water respectively for 2–2.5 years. A dose–response relationship could not be determined for either species because only one dose of aluminum was used and the type of tumors and organs in which they were found were not specified.
Significantly increased incidence of gross tumors was reported in male Long Evans rats and lymphoma leukemia in female Swiss mice given aluminum potassium sulfate in drinking water respectively for 2–2.5 years. A dose–response relationship could not be determined for either species because only one dose of aluminum was used and the type of tumors and organs in which they were found were not specified.
Environmental Fate
Aluminum binds diatomic phosphates and possibly depletes
phosphate, which can lead to osteomalacia. High aluminum
serum values and high aluminum concentration in the bone
interfere with the function of vitamin D. The incorporation of
aluminum in the bone may interfere with deposition of
calcium; the subsequent increase of calcium in the blood may
inhibit release of parathyroid hormones by the parathyroid
gland. The mechanism by which aluminum concentrates in the
brain is not known; it may interfere with the blood brain barrier.
Structure and conformation
The space lattice of Al belongs to the cubic system, and its face centered cubic lattice has a lattice constant of a=0.404145 nm (25 ℃).
Toxicity evaluation
Aluminum cannot be degraded in the environment in its
elemental state, but can undergo various precipitation or
ligand exchange reactions. The solubility of aluminum in the
environment depends on the ligands present and the pH.
Long-range transport
The major feature cycle of aluminum include leaching of aluminum from geochemical formations and soil particulates to aqueous environments, adsorption onto soil or sediment particulates, and wet and dry deposition from the air to land and surface water.
Bioaccumulation and biomagnification
Aluminum does not bioaccumulate to a significant extent. Thus, certain plants can accumulate high concentrations of aluminum. Plant matter like tea leaves may contain >5000 mg kg-1 of aluminum. Lycopodium, some fern species, and members of genera Symplocos or Orites may contain high levels of aluminum. It does not appear to accumulate to any significant degree in cow’s milk or beef tissue, and it is therefore not expected to undergo biomagnification in terrestrial food chains.
Long-range transport
The major feature cycle of aluminum include leaching of aluminum from geochemical formations and soil particulates to aqueous environments, adsorption onto soil or sediment particulates, and wet and dry deposition from the air to land and surface water.
Bioaccumulation and biomagnification
Aluminum does not bioaccumulate to a significant extent. Thus, certain plants can accumulate high concentrations of aluminum. Plant matter like tea leaves may contain >5000 mg kg-1 of aluminum. Lycopodium, some fern species, and members of genera Symplocos or Orites may contain high levels of aluminum. It does not appear to accumulate to any significant degree in cow’s milk or beef tissue, and it is therefore not expected to undergo biomagnification in terrestrial food chains.
Questions And Answer
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Description
Aluminum is the third most abundant element in the crust of the earth, accounting for 8.13% by weight. It does not occur in free elemental form in nature, but is found in combined forms such as oxides or silicates. It occurs in many minerals including bauxite, cryolite, feldspar and granite. Aluminum alloys have innumerable application; used extensively in electrical transmission lines, coated mirrors, utensils, packages, toys and in construction of aircraft and rockets.
aluminum powder ; -
Production Methods
Most aluminum is produced from its ore, bauxite, which contains between 40 to 60% alumina either as the trihydrate, gibbsite, or as the monohydrate, boehmite, and diaspore. Bauxite is refined first for the removal of silica and other impurities. It is done by the Bayer process. Ground bauxite is digested with NaOH solution under pressure, which dissolves alumina and silica, forming sodium aluminate and sodium aluminum silicate. Insoluble residues containing most impurities are filtered out. The clear liquor is then allowed to settle and starch is added to precipitate. The residue, so-called “red-mud”, is filtered out. After this “desilication,” the clear liquor is diluted and cooled. It is then seeded with alumina trihydrate (from a previous run) which promotes hydrolysis of the sodium aluminate to produce trihydrate crystals. The crystals are filtered out, washed, and calcined above 1,100°C to produce anhydrous alumina. The Bayer process, however, is not suitable for extracting bauxite that has high silica content (>10%). In the Alcoa process, which is suitable for highly silicious bauxite, the “red mud” is mixed with limestone and soda ash and calcined at 1,300°C. This produces “lime-soda sinter” which is cooled and treated with water. This leaches out water-soluble sodium alumnate, leaving behind calcium silicate and other impurites.
Alumina may be obtained from other minerals, such as nepheline, sodium potassium aluminum silicate, by similar soda lime sintering process.Metal aluminum is obtained from the pure alumina at 950 to 1000°C electrolysis (Hall-Heroult process). Although the basic process has not changed since its discovery, there have been many modifications. Aluminum is also produced by electrolysis of anhydrous AlCl3.
Also, the metal can be obtained by nonelectrolytic reduction processes. In carbothermic process, alumina is heated with carbon in a furnace at 2000 to 2500°C. Similarly, in “Subhalide” process, an Al alloy, Al-Fe-Si-, (obtained by carbothermic reduction of bauxite) is heated at 1250°C with AlCl vapor. This forms the subchloride (AlCl), the vapor of which decomposes when cooled to 800°C. ;
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