Page:A Treatise on Electricity and Magnetism - Volume 1.djvu/133

be formed. Of these one will be the surface of ${\displaystyle A_{r}}$ and its potential will be ${\displaystyle p_{rr}}$. If ${\displaystyle A_{s}}$ is placed in a hollow excavated in ${\displaystyle A_{r}}$ so as to be completely enclosed by it, then the potential of ${\displaystyle A_{s}}$ will also be ${\displaystyle p_{rr}}$.

If, however, ${\displaystyle A_{s}}$ is outside of ${\displaystyle A_{r}}$ its potential ${\displaystyle p_{rs}}$ will lie between ${\displaystyle p_{rr}}$ and zero.

For consider the lines of force issuing from the charged conductor ${\displaystyle A_{r}}$. The charge is measured by the excess of the number of lines which issue from it over those which terminate in it. Hence, if the conductor has no charge, the number of lines which enter the conductor must be equal to the number which issue from it. The lines which enter the conductor come from places of greater potential, and those which issue from it go to places of less potential. Hence the potential of an uncharged conductor must be intermediate between the highest and lowest potentials in the field, and therefore the highest and lowest potentials cannot belong to any of the uncharged bodies.

The highest potential must therefore be ${\displaystyle p_{rr}}$, that of the charged body ${\displaystyle A_{r}}$ , and the lowest must be that of space at an infinite distance, which is zero, and all the other potentials such as ${\displaystyle p_{rs}}$ must lie between ${\displaystyle p_{rr}}$ and zero.

If ${\displaystyle A_{s}}$ completely surrounds ${\displaystyle A_{t}}$ then ${\displaystyle p_{rs}}$ = ${\displaystyle p_{rt}}$.

91.] Theorem IV. None of the coefficients of induction are positive, and the sum of all those belonging to a single conductor is not numerically greater than the coefficient of capacity of that conductor, which is always positive.

For let ${\displaystyle A_{r}}$ be maintained at potential unity while all the other conductors are kept at potential zero, then the charge on ${\displaystyle A_{r}}$ is ${\displaystyle q_{rr}}$, and that on any other conductor ${\displaystyle A_{s}}$ is ${\displaystyle q_{rs}}$.

The number of lines of force which issue from ${\displaystyle A_{r}}$ is ${\displaystyle p_{rr}}$. Of these some terminate in the other conductors, and some may proceed to infinity, but no lines of force can pass between any of the other conductors or from them to infinity, because they are all at potential zero.

No line of force can issue from any of the other conductors such as ${\displaystyle A_{s}}$ , because no part of the field has a lower potential than ${\displaystyle A_{s}}$. If ${\displaystyle A_{s}}$ is completely cut off from ${\displaystyle A_{r}}$ by the closed surface of one of the conductors, then ${\displaystyle q_{rs}}$ is zero. If ${\displaystyle A_{s}}$ is not thus cut off, ${\displaystyle q_{rs}}$ is a negative quantity.

If one of the conductors ${\displaystyle A_{t}}$ completely surrounds ${\displaystyle A_{r}}$, then all the lines of force from ${\displaystyle A_{r}}$ fall on ${\displaystyle A_{t}}$ and the conductors within it,