Page:A Treatise on Electricity and Magnetism - Volume 1.djvu/142

If ${\displaystyle l,m,n}$ are the direction-cosines of the normal drawn inwards from the bounding surface at any point, and ${\displaystyle dS}$ an element of that surface, then we may write

${\displaystyle M=-\iint V(lu+mv+nw)dS-\iiint V({\frac {du}{dx}}+{\frac {dv}{dy}}+{\frac {dw}{dz}})\,dx\,dy\,dz}$;

the integration of the first term being extended over the bounding surface, and that of the second throughout the entire space.

For all spaces within which ${\displaystyle u,v,w}$ are continuous, the second term vanishes in virtue of equation (1). If for any surface within the space ${\displaystyle u,v,w}$ are discontinuous but subject to equation (2), we find for the part of ${\displaystyle M}$ depending on this surface,

${\displaystyle M_{1}=\iint V_{1}(l_{1}u_{1}+m_{1}v_{1}+n_{1}w_{1})dS_{1}}$,

${\displaystyle M_{2}=\iint V_{2}(l_{2}u_{2}+m_{2}v_{2}+n_{2}w_{2})dS_{2}}$;

where the suffixes ${\displaystyle _{1}}$ and ${\displaystyle _{2}}$, applied to any symbol, indicate to which of the two spaces separated by the surface the symbol belongs.

Now, since ${\displaystyle V}$ is continuous, we have at every point of the surface,

${\displaystyle V_{1}=V_{2}=V\,\!}$;

we have also

${\displaystyle dS_{l}=dS_{2}=dS\,\!}$;

but since the normals are drawn in opposite directions, we have

${\displaystyle l_{1}=-l_{2}=l,{\color {White}xxxx}m_{1}=m_{2}=m,{\color {White}xxxx}n_{1}=-n_{2}=n;}$

so that the total value of M, so far as it depends on the surface of discontinuity, is

${\displaystyle M_{1}+M_{2}=-\iint V(l(u_{1}-u_{2})+m(v_{1}-v_{2})+n(w_{1}-W_{2}))dS}$.

The quantity under the integral sign vanishes at every point in virtue of the superficial solenoidal condition or characteristic (2).

Hence, in determining the value of ${\displaystyle M}$, we have only to consider the surface-integral over the actual bounding surface of the space considered, or

${\displaystyle M=-\iint V(lu+mv+nw)dS}$.

Case 1. If V is constant over the whole surface and equal to ${\displaystyle C}$,

${\displaystyle M=-C\iint (lu+mv+nw)dS}$.

The part of this expression under the sign of double integration represents the surface-integral of the flux whose components are ${\displaystyle u,v,w,}$ and by Art. 21 this surface-integral is zero for the closed surface in virtue of the general and superficial solenoidal conditions (1) and (2).