Page:A Treatise on Electricity and Magnetism - Volume 1.djvu/211

integral of ${\displaystyle VY_{i}dS}$, extended over every element ${\displaystyle dS_{1}}$ of the surface of a sphere of radius ${\displaystyle a}$, is given by the equation

${\displaystyle \iint VY_{i}dS={\frac {4\pi }{|{\underline {i}}}}{\frac {a^{i+2}}{2i+1}}{\frac {d^{i}V}{dh_{1}\dots dh_{1}}};}$

(52)

where the differentiations of ${\displaystyle V}$ are taken with respect to the axes of the harmonic ${\displaystyle Y_{i}}$, and the value of the differential coefficient is that at the centre of the sphere.

136.] Let us now suppose that ${\displaystyle V}$ is a solid harmonic of positive degree ${\displaystyle j}$ of the form j

${\displaystyle V={\frac {r^{j}}{a^{j}}}Y_{j}.}$

(53)

At the spherical surface, ${\displaystyle r=a}$, the value of ${\displaystyle V}$ is the surface harmonic ${\displaystyle Y_{j}}$, and equation (52) becomes

${\displaystyle \iint Y_{i}Y_{j}dS={\frac {4\pi }{|{\underline {i}}}}{\frac {a^{i-j+2}}{2i+1}}{\frac {d^{i}\left(r^{j}Y_{j}\right)}{dh_{1}\dots dh_{i}}},}$

(54)

where the value of the differential coefficient is that at the centre of the sphere.

When ${\displaystyle i}$ is numerically different from ${\displaystyle j}$, the surface-integral of the product ${\displaystyle Y_{i}Y_{j}}$ vanishes. For, when ${\displaystyle i}$ is less than ${\displaystyle j}$, the result of the differentiation in the second member of (54) is a homogeneous function of x, y, and z, of degree ${\displaystyle j-i}$, the value of which at the centre of the sphere is zero. If ${\displaystyle i}$ is equal to ${\displaystyle j}$ the result is a constant, the value of which will be determined in the next article. If the differentiation is carried further, the result is zero. Hence the surface-integral vanishes when ${\displaystyle i}$ is greater than ${\displaystyle j}$.

137.] The most important case is that in which the harmonic ${\displaystyle r^{j}Y_{j}}$ is differentiated with respect to ${\displaystyle i}$ new axes in succession, the numerical value of ${\displaystyle j}$ being the same as that of ${\displaystyle i}$, but the directions of the axes being in general different. The final result in this case is a constant quantity, each term being the product of ${\displaystyle i}$ cosines of angles between the different axes taken in pairs. The general form of such a product may be written symbolically

${\displaystyle \mu _{ii}^{s}\mu _{jj}^{s}\mu _{ij}^{i-2s},}$

which indicates that there are ${\displaystyle s}$ cosines of angles between pairs of axes of the first system and ${\displaystyle s}$ between axes of the second system, the remaining ${\displaystyle i-2s}$ cosines being between axes one of which belongs to the first and the other to the second system.

In each product the suffix of every one of the ${\displaystyle 2i}$ axes occurs once, and once only.