of the deviation of the α rays compared with that of the β rays is much exaggerated in the figure.
73. Ionizing and penetrating power of the rays. Of
the three kinds of rays, the α rays produce most of the ionization
in the gas and the γ rays the least. With a thin layer of unscreened
active material spread on the lower of two parallel plates
5 cms. apart, the amount of ionization due to the α, β, and γ rays
is of the relative order 10,000, 100, and 1. These numbers are only
rough approximations, and the differences become less marked
as the thickness of the radio-active layer increases.
The average penetrating power of the rays is shown below. In the first column is given the thickness of the aluminium, which cuts each radiation down to half its value, and in the second the relative power of penetration of the rays.
++-++
| | Thickness of | |
| | Aluminium in cms. | Relative power |
| Radiation |which cuts off half| of penetration |
| | the radiation | |
++-++
| α rays | 0·0005 cms. | 1 |
| β " | 0·05 cms. | 100 |
| γ " | 8 cms. | 10000 |
++-++
The relative power of penetration is thus approximately inversely proportional to the relative ionization. These numbers, however, only indicate the order of relative penetrating power. This power varies considerably for the different active bodies.
The α rays from uranium and polonium are the least penetrating, and those from thorium the most. The β radiations from thorium and radium are very complex, and consist of rays widely different in penetrating power. Some of the β rays from these substances are much less and others much more penetrating than those from uranium, which gives out fairly homogeneous rays.
74. Difficulties of comparative measurements. It is
difficult to make quantitative or even qualitative measurements of
the relative intensity of the three types of rays from active substances.
The three general methods employed depend upon the
action of the rays in ionizing the gas, in acting on a photographic
