Magnesium ammonium nitrate chloride

Ammonium nitrate Sodium chloride Magnesium sulfate Potassium chloride Bacon oil (axonge oil) Water, balance to Trade Mark... [Pg.715]

Campbell and Ottaway [136] also used selective volatilisation of the cadmium analyte to determine cadmium in seawater. They could detect 0.04 pg/1 cadmium (2pg in 50 pi) in seawater. They dried at 100 °C and atomised at 1500 °C with no char step. Cadmium was lost above 350 °C. They could not use ammonium nitrate because the char temperature required to remove the ammonium nitrate also volatilised the cadmium. Sodium nitrate and sodium and magnesium chloride salts provided reduced signals for cadmium at much lower concentrations than their concentration in seawater if the atomisation temperature was in excess of 1800 °C. The determination required lower atomisation temperatures to avoid atomising the salts. Even this left the magnesium interference, which required the method of additions. [Pg.147]

Sodium hydroxide. Sodium cyanide. Bromine, Sulfuric acid Sulfuric acid. Bromine, Sodium cyanide Acetone, Sulfuric acid. Bromine, Methylene chloride Biguanide, Ethanol, Perchloric acid. Ethyl acetate l,3-Dichloro-2-propanol, Trioxane, 1,2-Dichloroethane, Sulfuric acid, Sodium bicarbonate, Dimethylsulfoxide, Sodium azide. Methylene chloride Ammonium nitrate, Nitromethane Ammonium nitrate, Hydrazine Sodium nitrate, Sulfur, Charcoal Potassium nitrate, Sulfur, Charcoal Magnesium powder, Hexachlorethane, Naphthalene... [Pg.96]

Ammonium nitrate, Diesel fuel TNT, Dioxane, Hydrogen sulfide gas. Ammonia, Hydrochloric acid. Potassium iodide, Sulfuric acid, Paraformaldehyde, Methylene chloride, Nitric acid, Magnesium sulfate. Chloroform, Methanol Ammonium nitrate. Sulfur... [Pg.134]

Ammonia gas, Carbon dioxide, Sodium chlorate Ammonia, Carbon dioxide. Sodium chlorate Hydrogen cyanide. Hydrocyanic acid. Prussic acid, Blausaure Hydrochloric acid. Methanol, ADNB, Methylene chloride. Nitric acid. Sodium bicarbonate. Magnesium sulfate 4,4-DNB, Methylene chloride. Magnesium sulfate. Sodium azide. Sodium hydroxide. Acetyl chloride. Ethyl acetate. Hexane TetranUine, Glacial acetic acid. Sodium azide Ammonium nitrate, TNT Sodium azide. Ammonia... [Pg.327]

Ethyl chloride. Magnesium metal turnings, Tetrahydrofuran, Arsenic trichloride. Hexanes Tetraethyl lead. Arsenic trichloride Ethylenediamine, Nitric acid. Ethanol Nitric acid. Ethanol, N,N"-Diethanolethylenediamine Dinitrate ethylene glycol. Nitric acid. Sulfuric acid Ammonium nitrate. Water, Oil, Oleic acid. Sodium hydroxide Sulfuric acid, Erythritol, Nitric acid. Sodium carbonate. Ethanol... [Pg.330]

Recent developments to the hydrothermal process include improvements in yield and reaction rate and in overcoming the difficulty associated with the coproduct salt. One method of overcoming the co-product problem is to use magnesium nitrate instead of chloride, with the ammonium nitrate being utiHsed for fertiliser production [102-104]. At least one plant based on this concept is now in commercial production. While a considerable advance on the initial chloride process, the nitrate route does require close integration with a fertiliser process and thus lacks flexibility. An alternative approach being developed is to recycle the ammonium salt co-product (nitrate or chloride) and use it to leach magnesium oxide, a potentially inexpensive raw material [103]. [Pg.101]

A family of high performance and clean space motor/gas generators and large launch vehicle solid propellants based on poly(GlyN) binder, ammonium nitrate oxidizer and small amounts of aluminum and/or boron with optimized performance at low solids loading (without the presence of plasticizers) and also poly(GlyN) binder, ammonium nitrate oxidizer and aluminum or magnesium fuel have been reported in the literature [141, 142]. These solid propellant formulations produce essentially no HC1 or chloride ions in the exhaust and are considered eco-friendly. [Pg.260]

The data set treated in this study is a part of the above-mentioned measurements in the Struma River basin. The period of observation in this region was 10 years (1989-98), and the chemical indicators were pH, dissolved oxygen, BOD5, COD, conductivity, acidity, DISS, N-DISS, total hardness, chloride, sulfate, ammonium, nitrate, nitrite, iron, magnesium, and calcium. [Pg.382]

Sodium chloride Sodium bromide Sodium iodide Sodium sulphate Sodium silicate Potassium sulphate Lithium chloride Calcium carbonate Calcium sulphate Magnesium sulphate Manganous carbonate Ferrous carbonate. Aluminium phosphate Ammonium nitrate Organic matter... [Pg.210]

C—F 7.(a) 1.26, non-polar molecule (b) 0.97, polar molecule (c) 1.55, non-polar molecule 3.4 1.(a) potassium chromate (b) ammonium nitrate (c) sodium sulfate (d) strontium phosphate (e) potassium nitrite (f) barium hypochlorite 2.(a) magnesium chloride (b) sodium oxide... [Pg.109]

Ammonium perchlorate, NH4C104.—The perchlorate is formed by mixing solutions of barium perchlorate and ammonium sulphate, by the action of ammonium nitrate on sodium perchlorate,8 and by that of ammonium chloride on calcium or magnesium perchlorate.10 It forms rhombic,11 doubly refracting crystals,12 of density 1 88 at 25° C. Its solubility at 18° C. is 21 07 grams in 100 grams of water.18 It is de-... [Pg.218]

Explosive reaction with chlorosulfuric acid, hydroiodic acid, magnesium perchlorate, chromyl chloride. Forms sensitive explosive mixtures with metal halogenates (e.g., chlorates, bromates, or iodates of barium, calcium, magnesium, potassium, sodium, zinc), ammonium nitrate, mercury(1) nitrate, silver nitrate, sodium nitrate, potassium permanganate. Violent reaction or ignition with alkalies + heat, fluorine, chlorine, liquid bromine, antimony pentachloride. Reacts with hot alkalies or hydroiodic acid to form... [Pg.1118]

The growth medium includes defined salts, complex nutrients, surfactants, and inducer. The salts are the typical fermentation salts, including potassium phosphate, ammonium nitrate, ammonium sulfate, calcium chloride, and magnesium sulfate [33]. The complex nutrients are most often 5 to 25 g L of corn steep liquor but can also include yeast extract. The surfactants are added to control or suppress foam formation. The surfactants used include commercial antifoams as well as soybean oil or palm oil. The inducers are proprietary to each manufacturer but will contain an inexpensive mixture of soluble and/or insoluble sugars. Some inducers used include milk whey, which contains lactose Solka floe cellulose or, sugar or paper mill waste streams. [Pg.56]