1285. The charges were low in these experiments, first that they might not pass off at low pressure, and next that little loss by dissipation might occur. I now reduced them still lower, that I might rarefy further, and for this purpose in the following experiment used a measuring interval in the electrometer of only 15° (1185.). The pressure of air within the apparatus being reduced to 1.9 inches of mercury, the charge was found to be 29°; then letting in air till the pressure was 30 inches, the charge was still 29°.
1286. These experiments were repeated with pure oxygen with the same consequences.
1287. This result of no variation in the electric tension being produced by variation in the density or pressure of the air, agrees perfectly with those obtained by Mr. Harris[241], and described in his beautiful and important investigations contained in the Philosophical Transactions; namely that induction is the same in rare and dense air, and that the divergence of an electrometer under such variations of the air continues the same, provided no electricity pass away from it. The effect is one entirely independent of that power which dense air has of causing a higher charge to be retained upon the surface of conductors in it than can be retained by the same conductors in rare air; a point I propose considering hereafter.
1288. I then compared hot and cold air together, by raising the temperature of one of the inductive apparatus as high as it could be without injury, and then dividing charges between it and the other apparatus containing cold air. The temperatures were about 50° and 200°, Still the power or capacity appeared to be unchanged; and when I endeavoured to vary the experiment, by charging a cold apparatus and then warming it by a spirit lamp, I could obtain no proof that the inductive capacity underwent any alteration.
1289. I compared damp and dry air together, but could find no difference in the results.
* * * * *
1290. Gases.—A very long series of experiments was then undertaken for the purpose of comparing different gases one with another. They were all found to insulate well, except such as acted on the shell-lac of the supporting stem; these were chlorine, ammonia, and muriatic acid. They were all dried by appropriate means before being introduced into the apparatus. It would have been sufficient to have compared each with air; but, in consequence of the striking result which came out, namely, that all had the same power of or capacity for, sustaining induction through them, (which perhaps might have been expected after it was found that no variation of density or pressure produced any effect,) I was induced to compare them, experimentally, two and two in various ways, that no difference might escape me, and that the sameness of result might stand in full opposition to the contrast of property, composition, and condition which the gases themselves presented.
1291. The experiments were made upon the following pairs of gases.
| 1. | Nitrogen and | Oxygen. |
| 2. | Oxygen | Air. |
| 3. | Hydrogen | Air. |
| 4. | Muriatic acid gas | Air. |
| 5. | Oxygen | Hydrogen. |
| 6. | Oxygen | Carbonic acid. |
| 7. | Oxygen | Olefiant gas. |
| 8. | Oxygen | Nitrous gas. |
| 9. | Oxygen | Sulphurous acid. |
| 10. | Oxygen | Ammonia. |
| 11. | Hydrogen | Carbonic acid. |
| 12. | Hydrogen | Olefiant gas. |
| 13. | Hydrogen | Sulphurous acid. |
| 14. | Hydrogen | Fluo-silicic acid. |
| 15. | Hydrogen | Ammonia. |
| 16. | Hydrogen | Arseniuretted hydrogen. |
| 17. | Hydrogen | Sulphuretted hydrogen. |
| 18. | Nitrogen | Olefiant gas. |
| 19. | Nitrogen | Nitrous gas. |
| 20. | Nitrogen | Nitrous oxide. |
| 21. | Nitrogen | Ammonia. |
| 22. | Carbonic oxide | Carbonic acid. |
| 23. | Carbonic oxide | Olefiant gas. |
| 24. | Nitrous oxide | Nitrous gas. |
| 25. | Ammonia | Sulphurous acid. |
1292. Notwithstanding the striking contrasts of all kinds which these gases present of property, of density, whether simple or compound, anions or cations (665.), of high or low pressure (1284. 1286.), hot or cold (1288.), not the least difference in their capacity to favour or admit electrical induction through them could be perceived. Considering the point established, that in all these gases induction takes place by an action of contiguous particles, this is the more important, and adds one to the many striking relations which hold between bodies having the gaseous condition and form. Another equally important electrical relation, which will be examined in the next paper[242], is that which the different gases have to each other at the same pressure of causing the retention of the same or different degrees of charge upon conductors in them. These two results appear to bear importantly upon the subject of electrochemical excitation and decomposition; for as all these phenomena, different as they seem to be, must depend upon the electrical forces of the particles of matter, the very distance at which they seem to stand from each other will do much, if properly considered, to illustrate the principle by which they are held in one common bond, and subject, as they must be, to one common law.