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Aluminum silicon sodium oxide

Al2Na20i4Si5 XH2O. Aluminum silicon sodium oxide (Al2Si5Na20(4). hydrate. [117314-29-1]. 30 229... [Pg.277]

Iron zinc oxide (Fe29ZnQ 1O4), 30 127 [117004-16-7). Barium bismuth potassium oxide (Baa6BiKo.403), 30 198 [117314-29-1), Aluminum silicon sodium oxide (Al2Si5Na20 4), hydrate. 30 229 1118392-28-2). Cobalt sodium oxide (CoNsq J44) 74O2). 30 149 ) 118557-22-5), Calcium copper lead strontium yttrium oxide (Co5CujPb2Sr2Yo.50g). 30 197 ) 118955-75-2). Niobium titanium hydroxide oxide (NbTi(OH)04). 30 184 (120525-55-5). Boric acid (HjBOj). [Pg.300]

Sillimanite, see Aluminum silicon oxide (1/1) Smithsonite, see Zinc carbonate Soda ash, see Sodium carbonate Spelter, see Zinc metal Sphalerite, see Zinc sulflde Spherocobaltite, see Cobalt(II) carbonate Spinel, see Magnesium aluminate(2—)... [Pg.275]

In 1885, Charles Martin Hall invented his aluminum process and Hamilton Young Castner in 1890 developed the mercury-type alkali-chlorine cell, which produced caustic (sodium hydroxide) in its purest form. Edward G. Acheson in 1891, while attempting to make diamonds in an electric furnace, produced silicon carbide, the first synthetic abrasive, second to diamond in hardness. Four years later, Jacobs melted aluminum oxide to make a superior emeiy cloth. Within two decades, these two abrasives had displaced most natural cutting materials, including naturally occurring mixtures of aluminum and iron oxides. [Pg.234]

The wavelength-dispersive x-ray spectroscopy method (ASTM D6376) provides a rapid means of measuring metallic elements in coke and provides a guide for determining conformance to material specifications. A benefit of this method is that the sulfur content can also be used to evaluate potential formation of sulfur oxides, a source of atmospheric pollution. This test method specifically determines sodium, aluminum, silicon, sulfur, calcium, titanium, vanadium, manganese, iron, and nickel. [Pg.301]

Thermal reduction processes have been apphed successfully in making the metal from salts. In one such process, potassium fluotantalate is reduced with sodium metal at high temperatures to form tantalum powder of high purity and small particle size. Also, tantalum oxide can be reduced at high temperatures in vacuum with aluminum, silicon, or tantalum carbide. When the oxide is reduced by tantalum carbide, a metal sponge is obtained which can be embrittled with hydrogen to form powder metal. [Pg.909]

North Carolina kaolin has the following chemical composition silicon dioxide, Si02,46.18% aluminum oxide, A1203, 38.38% water, H20, 13.28% sodium oxide, Na20, 1.22% iron oxide, Fe203,. 57% and magnesium oxide, MgO,. 42%. [Pg.153]

Typical fuels are magnesium (sometimes mixed with aluminum), manganese, and silicon. Typical oxidizers include the nitrates of barium, sodium, potassium, and strontium. Binders used are castor and linseed oils and paraffin waxes. Another interesting flare mix is magnesium or teflon. The chlorine and fluorine from the teflon are the oxidizers in this mix. Magnesium or teflon flares burn several hundred degrees (°C) hotter than metal or salt flares and radiate very strongly in the infrared spectrum. [Pg.456]

Kaolin is a white clay mostly made up of silicon dioxide, aluminum oxide, iron oxide, titanium dioxide, magnesium oxide and sodium oxide. It was first found in China, in Kao-Ling. European kaolin is formed by the decomposition of feldspath in granite rock in Brittany or Limousin. Kaolin has good absorbent properties and is gentle on the skin it is very well tolerated by very sensitive or reactive skins. It is used for its healing, antiseptic and anti-inflammatory qualities and its excellent coverage in Unna s paste formula. [Pg.184]

CARBON OXYCHLORIDE (75-44-5) COCI2 Highly toxic and corrosive gas. Deconqioses slowly with water, producing hydrochloric acid and carbon oxides. Deconqjoses above 572°F/300°C, forming toxic and corrosive gases of hydrogen chloride and carbon monoxide chlorine. Reacts violently with strong oxidizers, amines, alkalis, anhydrous ammonia, isopropanol, chemically active metals aluminum, silicon tetrahydride, sodium. Forms shock-sensitive material with potassium. Incompatible with tert-alcohols. [Pg.219]

PLUMBOUS OXIDE (1317-36-8) PbO An oxidizer. Explosive reaction with 90% peroxyformic acid, mbidium acetylide. Reacts violently with strong oxidizers, aluminum carbide boron, chlorine, fluorine, dichloromethylsilane, calcium sulfide, hydrogen peroxide, hydrogen trisulfide (ignition), hydroxylamine (ignition), lithium carbide, metal acetylides, metal powders (e.g., aluminum, molybdenum, sodium, zirconium, etc.), perchloric acid, red phosphorus, selenium oxychloride, sodium. Incompatible with barium sulfide, chemically active metals silicon, sulfuryl chloride. [Pg.883]


See other pages where Aluminum silicon sodium oxide is mentioned: [Pg.2865]    [Pg.172]    [Pg.342]    [Pg.324]    [Pg.153]    [Pg.26]    [Pg.495]    [Pg.99]    [Pg.2508]    [Pg.259]    [Pg.30]    [Pg.218]    [Pg.221]    [Pg.229]    [Pg.245]    [Pg.630]    [Pg.630]    [Pg.642]    [Pg.642]    [Pg.862]    [Pg.889]    [Pg.697]    [Pg.699]    [Pg.699]    [Pg.699]    [Pg.700]    [Pg.953]    [Pg.1345]    [Pg.852]    [Pg.54]    [Pg.190]    [Pg.506]    [Pg.246]    [Pg.54]   


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Aluminum oxidation

Aluminum oxide

Aluminum oxidized

Oxidation silicones

Oxides silicon oxide

Oxidized silicon

Silicon oxidation

Silicon oxides

Silicon-aluminum

Sodium aluminum

Sodium oxidation

Sodium oxide

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