Page:A Treatise on Electricity and Magnetism - Volume 2.djvu/295

Rh Now $$p$$, the electrokinetic momentum of the circuit, was shewn in Art. 588 to be measured by the surface-integral of magnetic induction through the circuit. Hence, in the case of a current-sheet of no resistance, the surface-integral of magnetic induction through any closed curve drawn on the surface must be constant, and this implies that the normal component of magnetic induction remains constant at every point of the current-sheet.

655.] If, therefore, by the motion of magnets or variations of currents in the neighbourhood, the magnetic field is in any way altered, electric currents will be set up in the current-sheet, such that their magnetic effect, combined with that of the magnets or currents in the field, will maintain the normal component of magnetic induction at every point of the sheet unchanged. If at first there is no magnetic action, and no currents in the sheet, then the normal component of magnetic induction will always be zero at every point of the sheet.

The sheet may therefore be regarded as impervious to magnetic induction, and the lines of magnetic induction will be deflected by the sheet exactly in the same way as the lines of flow of an electric current in an infinite and uniform conducting mass would be deflected by the introduction of a sheet of the same form made of a substance of infinite resistance.

If the sheet forms a closed or an infinite surface, no magnetic actions which may take place on one side of the sheet will produce any magnetic effect on the other side.

656.] We have seen that the external magnetic action of a current-sheet is equivalent to that of a magnetic shell whose strength at any point is numerically equal to $$\phi$$, the current-function. When the sheet is a plane one, we may express all the quantities required for the determination of electromagnetic effects in terms of a single function, $$P$$, which is the potential due to a sheet of imaginary matter spread over the plane with a surface-density $$\phi$$. The value of $$P$$ is of course Rhwhere $$r$$ is the distance from the point ($$x,$$ $$y$$, $$z$$) for which $$P$$ is calculated, to the point $$x^\prime$$, $$y^\prime$$, $$0$$ in the plane of the sheet, at which the element $$dx^\prime\, dy^\prime$$ is taken.

To find the magnetic potential, we may regard the magnetic