Simple Scalar Surface Integrals

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Section 3.12 Simple Scalar Surface Integrals

What is the surface area of a sphere of radius \(a\text{?}\) You surely know the answer: \(4\pi a^2\text{.}\) But do you know why?

How do you chop up a sphere? In spherical coordinates, of course. As we have seen in Section 3.11, an infinitesimal rectangle on the surface of the sphere has sides \(r\,d\theta\) and \(r\,\sin\theta\,d\phi\text{,}\) so the scalar surface element on a sphere is

\begin{equation} dA = r^2\sin\theta\,d\theta\,d\phi\tag{3.12.1} \end{equation}

and we know that \(r=a\text{.}\) The surface area is simply the sum of these infinitesimal areas:

\begin{align*} A = \int dA \amp = \int_0^{2\pi}\int_0^\pi a^2 \sin\theta\,d\theta\,d\phi\\ \amp = 2\pi a^2 (-\cos\theta)\Big|_0^\pi = 4\pi a^2 \nonumber \end{align*}

(How did we choose the limits of integration?)

Now suppose the charge density on the surface of a sphere is not constant and is given by

\begin{equation} \sigma=\frac{15}{8\pi}\sin^2\theta\,\cos^2\theta .\tag{3.12.2} \end{equation}

How much total charge is there on the surface of the sphere?

The limits of integration are the same, so now we have

\begin{align*} Q = \int \sigma\, dA \amp= \int_0^{2\pi}\int_0^\pi \frac{15}{8\pi} \sin^3\theta\,\cos^2\theta\,d\theta\,d\phi \nonumber\\ \amp= \frac{15}{4} \int_0^\pi \left( \cos^2\theta-\cos^4\theta \right) \sin\theta\, d\theta\\ \amp= \frac{15}{4} \left( \frac{\cos^5\theta}{5}-\frac{\cos^3\theta}{3} \right) \Bigg|_0^\pi = 1 .\nonumber \end{align*}