·59 mm. and 6·0 mms. With a small voltage, the amount on the negative electrode varied with its diameter. The curves showing the relation between the amount of excited activity and voltage are very similar in character to those obtained for the variation of the current through an ionized gas with the voltage applied.
The amount of excited activity reaches a maximum when all the active matter is removed from the gas as rapidly as it is formed. With weaker fields, a portion diffuses to the sides of the vessel, and produces excited activity on the positive electrode.
189. Effect of pressure on distribution of excited activity. In a strong electric field, the amount of excited activity
produced on the cathode is independent of the pressure down to a
pressure of about 10 mms. of mercury. In some experiments made
by the writer[1], the emanating thorium compound was placed
inside a closed cylinder about 4 cms. in diameter, through which
passed an insulated central rod. The central rod was connected to
the negative pole of a battery of 50 volts. When the pressure was
reduced below 10 mms. of mercury, the amount of excited activity
produced on the negative electrode diminished, and was a very
small fraction of its original value at a pressure of 1/10 mm. Some
excited activity was in this case found to be distributed over the
interior surface of the cylinder. It may thus be concluded that at
low pressures the excited activity appears on both anode and
cathode, even in a strong electric field. The probable explanation
of this effect is given in the next section.
Curie and Debierne[2] observed that when a vessel containing an emanating radium compound was kept pumped down to a low pressure, the amount of excited activity produced on the vessel was much reduced. In this case the emanation given off by the radium was removed by the pump with the other gases continuously evolved from the radium compound. On account of the very slow decay of activity of the emanation, the amount of excited activity produced on the walls of the vessel, in the passage of the emanation through it, was only a minute fraction of the amount produced when none of the emanation given off was allowed to escape.