The chief difficulty in connection with the preparation of pure nitrogen lies in the removal of the nitric oxide which is produced in small quantity by most of the reactions in which nitrogen is the chief product. Nitric oxide is an extremely stable compound, and can only be eliminated by passing the gas through a tube containing metallic iron or copper, heated to a redness. The use of iron is to be avoided, since a trace of moisture entering the tube gives rise to the production of hydrogen.

Lord Rayleigh's results show that nitrogen, practically free from nitric oxide, can be prepared by heating a solution of ammonium chloride and potassium nitrite on a water -bath, passing the gas through a tube containing red-hot copper, and subsequently through caustic potash, sulphuric acid, and pentoxide of phosphorus

If the presence of argon does not materially affect the result, and it is merely required to prepare a quantity of nitrogen in order to carry out some process which it is necessary to conduct in an atmosphere of inert gas, the following method may te applied. Atmospheric air is drawn slowly through a solution of strong ammonia, contained in a wash-bottle, through a tube containing metallic copper heated to a red heat, and finally through a vessel containing strong sulphuric acid to remove moisture and excess of ammonia. The volume of the nitrogen obtained by this process is nearly equivalent to the quantity of air used.

It may be as well to state here, by way of warning, that metals generally are not nearly so inactive with regard to nitrogen as they were formerly supposed to be. Most metals appear to combine slowly with nitrogen, forming nitrides.

Atmospheric nitrogen for use in pressure gauges, etc. (pp.164, 230) may be obtained by passing air through a tube containing copper, and subsequently through caustic potash, etc.

Lord Eayleigh (Ch Soc. Jour, 1897, 181) has described a process for the preparation of argon on a large scale by sparking atmospheric air with oxygen.

The absorption of the oxygen and nitrogen was conducted in three stages In the first, the oxygen was removed by means of metallic copper ; in the second, the nitrogen was passed twice over metallic magnesium.

Atmospheric nitrogen was obtained by drawing air, freed from carbon dioxide by passage through caustic soda solution, over heated metallic copper. A large iron tube F, 3 feet 6 inches long and 3 5 inches in diameter, containing 25 Ibs. of scrap copper, was connected with the gasholder A; the tube was
heated in a long fire-brick trough during these experiments, but a gas-furnace, which is shown in the figure, has now been substituted for the more primitive arrangement. The time required to fill the gasholder was -usually about live hours, and it was found, on analysis of the gas, that one
single operation sufficed for the complete removal of all oxygen. The oxidised copper was reduced between each operation by means of coal-gas

Ozone, O3. Although it is impossible to obtain ozone free from oxygen, it is convenient to include in this chapter a description of the methods employed in manipulating it. A mixture of ozone and oxygen may be obtained by subjecting pure oxygen to the influence of the silent discharge. Nitrogen must be absent, since the conditions which favour the production of ozone lead also to the formation of oxides of nitrogen. The gas must not be brought into contact either with rubber or with mercury, both of which are attacked by ozone. The gas does not, however, act upon paraffin, and stopcocks may be lubricated with metaphosphoric acid.

The quantity of ozone, that is to say the percentage of ozone in the mixture, varies with the nature of the discharge, with the temperature, and with
the quantity of moisture present in the gas. The following are the more important points to be kept in mind in designing the apparatus
(i) The ozoniser must be kept cool.
(ii) The ozoniser must be made of thin glass of uniform thickness.
(iii) The two surfaces between which the discharge is passed, should be as close together as possible (Shenstone and Priest, Okem. Soc. Jour., 1893, 63, 952).

For the production of ozone in large quantity the Andreoli ozonizer appears to be the most efficient. It consists of a number of flat rings of pewter toothed on the inside, and connected longitudinally by strips of metal to form a cage.
...
With regard to the nature of the discharge, Shenstone and Priest state that he difference of potential should not be too grea, and that interruptions should not exceed one thousands per minutes. It appears, however, that the intensity of the discharge should bear some relation to the rate of flow of the gas, and that for a rapid current a high potentual maybe used with advantage. In the later case a large coil should be employed (see also p241).

The experiment is a dangerous one, though Troost states that liquid ozone is- non-explosive in the absence of organic matter.

- During lean burn operation, the NOx adsorbent in the lower layer adsorbs NOx from the exhaust gas.
- As needed, the engine management system adjusts the engine air-fuel ratio to rich-burn, wherein the NOx in the NOx adsorption layer reacts with hydrogen (H2) obtained from the exhaust gas to produce ammonia (NH3).The adsorbent material in the upper layer temporarily adsorbs the NH3.
-When the engine returns to lean-burn operation, NH3 adsorbed in the upper layer reacts with NOx in the exhaust gas and reduces it to harmless nitrogen (N2).