Page:A Treatise on Electricity and Magnetism - Volume 1.djvu/266

The result of this investigation is that if ${\displaystyle f}$ is the diameter of the sphere, ${\displaystyle a}$ the chord of the radius of the bowl, and ${\displaystyle r}$ the chord of the distance of ${\displaystyle P}$ from the pole of the bowl, then the surface-density ${\displaystyle \sigma }$ on the inside of the bowl is

${\displaystyle \sigma ={\frac {V}{2\pi ^{2}f}}\left\{{\sqrt {\frac {f^{2}-a^{2}}{a^{2}-r^{2}}}}-\tan ^{-1}{\sqrt {\frac {f^{2}-a^{2}}{a^{2}-r^{2}}}}\right\},}$

and the surface-density on the outside of the bowl at the same point is

${\displaystyle \sigma +{\frac {V}{2\pi f}}.}$

In the calculation of this result no operation is employed more abstruse than ordinary integration over part of a spherical surface. To complete the theory of the electrification of a spherical bowl we only require the geometry of the inversion of spherical surfaces.

181.] Let it be required to find the surface-density induced at any point of the bowl by a quantity ${\displaystyle q}$ of electricity placed at a point ${\displaystyle Q}$, not now in the spherical surface produced.

Invert the bowl with respect to ${\displaystyle Q}$, the radius of the sphere of inversion being ${\displaystyle R}$. The bowl ${\displaystyle S}$ will be inverted into its image ${\displaystyle S'}$, and the point ${\displaystyle P}$ will have ${\displaystyle P'}$ for its image. We have now to determine the density ${\displaystyle \sigma '}$ at ${\displaystyle P'}$ when the bowl ${\displaystyle S'}$ is maintained at potential ${\displaystyle V'}$, such that ${\displaystyle q=V'R}$, and is not influenced by any external force.

The density ${\displaystyle \sigma }$ at the point ${\displaystyle P}$ of the original bowl is then

${\displaystyle \sigma =-{\frac {\sigma 'R^{3}}{QP^{3}}},}$

this bowl being at potential zero, and influenced by a quantity ${\displaystyle q}$ of electricity placed at ${\displaystyle Q}$.

The result of this process is as follows:

Fig. 16.

Let the figure represent a section through the centre, ${\displaystyle O}$, of the sphere, the pole, ${\displaystyle C}$, of the bowl, and the influencing point ${\displaystyle Q}$. ${\displaystyle D}$ is a point which corresponds in the inverted figure to the unoccupied pole of the rim of the bowl, and may be found by the following construction.

Draw through ${\displaystyle Q}$ the chords ${\displaystyle EQE'}$ and ${\displaystyle FQF'}$, then if we suppose the radius of the sphere of inversion to be a mean proportional between the segments into which a chord is divided at ${\displaystyle Q}$, ${\displaystyle E'F'}$ will be the