|
#1
|
||||
|
||||
Παραγωγή Οξυγόνου...
Preparation
Because oxygen is a component of air, it has been studies extensively over the centuries and there is a large number of different methods for its preparation. The most convenient method for preparing oxygen in the laboratory involves either the catalytic decomposition of solid potassium chlorate or the catalytic decomposition of hydrogen peroxide. Preparation of oxygen Using potassium chlorate Potassium chlorate decomposes at a low temperature if previously mixed with manganese dioxide which is a catalyst for the decomposition. Only the potassium chlorate is decomposed, and no perchlorate is formed : 2 KClO3 ==> 2 KCl + 3 O2 Preparation of oxygen using hydrogen peroxide The decomposition of hydrogen peroxide using manganese dioxide as a catalyst also results in the production of oxygen gas. 2 H2O2 ==> 2 H2O + O2 Preparation of oxygen by electrolysis of water The electrolysis of acidified water is carried out in a Hofmann Voltameter. Oxygen is evolved at the positive electrode in the electrolysis. 2 H2O ==> 2 H2 + O2 A solution of barium hydroxide with nickel electrodes may also be used. However, on prolonged electrolysis an explosive mixture of oxygen and hydrogen may be evolved at the positive electrode. Preparation of oxygen by the chemical decomposition of water Oxygen is obtained from water by passing a mixture of steam and chlorine through a strongly heated silica tube containing pieces of broken porcelain. 2 H2O + 2 Cl2 ==> 4 HCl + O2 The hydrogen chloride is removed by a wash-bottle containing sodium hydroxide solution and the Oxygen collected over water. Preparation of oxygen By decomposition of oxides Oxygen may be obtained by heating some metallic oxides.
Some salts containing oxygen decompose and release oxygen gas on heating.
Oxygen may be obtained from the atmosphere in a chemical process, by heating mercury in a confined volume of air, when the oxygen reacts with the mercury to form mercuric oxide. The mercuric oxide so formed is then heated strongly, when it decomposes and pure oxygen is evolved. In a similar process, if yellow lead monoxide is carefully heated in an iron dish and freely exposed to air, it takes up oxygen from the air and forms red lead. 6 PbO + O2 ==> 2 Pb3O4 Yellow Red Lead Lead Monoxide On heating strongly, the red lead decomposes into lead monoxide and Oxygen gas which is evolved. 2 Pb3O4 ==> 6 PbO + O2 Manufacture Oxygen, the second-largest volume industrial gas, is produced commercially as a gas or as a liquid by several methods. These include: » Cryogenic Air separation, a process that compresses and cools atmospheric air, then, - relying on different boiling points - separates the resulting liquid into its components in a distillation column» Vacuum Pressure Swing Adsorption (VPSA), a non-cryogenic technology that produces oxygen from air by using an adsorbent in a pressure swing process to remove nitrogen Various methods have been used for the large scale production of oxygen, but at present the two mostly used are the electrolysis of an aqueous solution of dilute sulphuric acid, and the fractional distillation of Liquid Air. Manufacture from liquefied air Oxygen may be obtained from the atmosphere by the liquefaction and fractional distillation of air. Liquid air is a mixture of liquid nitrogen, boiling point -196 degC, and liquid oxygen, boiling point -183 degC. The nitrogen is more volatile (i.e. it has a lower boiling point) and boils off first during evaporation. Because some oxygen evaporates with the nitrogen, separation of the two gases is brought about by fractionation (i.e. by letting the evolved gas mixture bubble through liquid air rich in oxygen in a tall rectifying column). The oxygen in the gas mixture condenses and almost pure nitrogen gas leaves the top of the column, leaving almost pure liquid oxygen which is then evaporated to give oxygen gas. The oxygen gas is distributed as a compressed gas in high pressure cylinders.
__________________
I never get narced, or pee in my wetsuit |
|
|