| No. of layers of paper | Current |
|---|---|
| 0 | 1 |
| 1 | ·37 |
| 2 | ·16 |
| 3 | ·08 |
Table II. Thick Layer.
Thickness of paper ·008 cm.
| No. of layers of paper | Current |
|---|---|
| 0 | 1 |
| 1 | ·74 |
| 2 | ·74 |
| 5 | ·72 |
| 10 | ·67 |
| 20 | ·55 |
The initial current with the unscreened compound is taken as unity. In Table I, for a thin layer of thorium oxide, the current diminished rapidly with additional layers of thin paper. In this case the current is due almost entirely to the α rays. In Table II the current falls to ·74 for the first layer. In this case about 26% of the current is due to the α rays, which are practically absorbed by the layer ·008 cm. in thickness. The slow decrease with additional layers shows that the emanation diffuses so rapidly through a few layers of paper that there is little loss of activity during the passage. The time taken to diffuse through 20 layers is however appreciable, and the current consequently has decreased. After passing through a layer of cardboard 1·6 mms. in thickness the current is reduced to about one-fifth of its original value. In closed vessels the proportion of the total current, due to the emanation, varies with the distance between the plates as well as with the thickness of the layer of active material. It also varies greatly with the compound examined. In the nitrate, which gives off only a small amount of emanation, the proportion is very much smaller than in the hydroxide, which gives off a large amount of emanation.
143. Increase of current with time. The current due to the emanation does not reach its final value for some time after the active matter has been introduced into the closed vessel. The variation with time is shown in the following table. The saturation current due to thorium oxide, covered with paper, was observed between concentric cylinders of 5·5 cms. and ·8 cm. diameter.
Immediately before observations on the current were made, a rapid stream of air was blown through the apparatus. This removed most of the emanation. However, the current due to the ionization of the gas by the emanation, as it was carried along by the current of air, was still appreciable. The current consequently does not start from zero.
| Time in seconds | Current |
| 0 | 9 |
| 23 | 25 |
| 53 | 49 |
| 96 | 67 |
| 125 | 76 |
| 194 | 88 |
| 244 | 98 |
| 304 | 99 |
| 484 | 100 |
The results are shown graphically in [Fig. 52], curve B. The decay of the activity of the emanation with time, and the rate of increase of the activity due to the emanation in a closed space, are connected in the same way as the decay and recovery curves of Th X and Ur X.
With the previous notation, the decay curve is given by